Veer Towers East Download PDF


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Figures

Height: Architectural 137 m / 449 ft
Height: Occupied 129.1 m / 424 ft
Height: To Tip 140.2 m / 460 ft
Floors Above Ground 36
Floors Below Ground 2
# of Elevators 4

Facts

Official Name Veer Towers East
Name of Complex CityCenter
Structure Type Building
Status Completed
Country United States
City Las Vegas
Street Address & Map 3722 Las Vegas Boulevard South
Postal Code 89109
Building Function residential
Structural Material concrete
Energy Label LEED Gold
Proposed 2006
Construction Start 2006
Completion 2010
Official Website City Center Las Vegas

Companies Involved

Owner MGM Mirage
Developer MGM Mirage Design Group
Architect
Design Murphy/Jahn Architects
Architect of Record Adamson Associates
Structural Engineer
Design Halcrow Yolles
MEP Engineer
Design WSP Flack + Kurtz
Main Contractor Perini Corporation; Tishman Construction
Other Consultant
Façade Vidaris, Inc.; Far East Aluminum Works Co., Ltd.

About Veer Towers East

Part of the new CityCenter complex in Las Vegas, Veer Towers attempts to blur the boundaries between the public and private realm while finding the right balance between becoming an integral part of the city while also giving the buildings and spaces a unique and iconic character. In approaching the design of the towers, the context was not a historical background to build upon, but the framework to establish a new order and create a new image. The Veer Towers lean at five degrees in opposite directions creating an architecture that is at once robust and delicate.

There’s no reflective glass used on the project, making Veer the first truly transparent building in Las Vegas. Extensive use of high performance low-E coating glazing maximizes the introduction of day lighting and views to the outside, which in conjunction with the use of exterior shades and a 57% ceramic frit in 50% of the building’s envelope, provide all the shading to control and reduce the solar loads. Staggered panels of clear and fritted yellow glass animate the façades and give the complex a welcome shot of color while horizontal louvers add a depth and texture to the exterior as well as provide shade from the intense desert sun.

The load-bearing structure is a simple and repetitive system with a Z-shaped central core. The cores of both towers are strategically positioned on the building’s footprint in order to minimize gravity overturning effects, and they continue vertically up the entire building height. While all interior columns rise straight vertically, the tower columns on the north and south building elevations are inclined to follow the lean of the towers.

The south façade of the main building lobbies are expressed with slender concrete columns free standing at over 24m (80ft) high and inclined to articulate the lean of the towers. Due to space constraints and the requirement to maximize usable lobby space, composite column construction was introduced. The architectural design of the main lobby required a unique solution to the heating, cooling and ventilation due to the distinctive nature of these spaces. Each lobby is a multi-level space with a large expanse of glass on the south façade which runs the full height of the space. It provides large quantities of natural light to the lobby and large solar heat gains in summer and heat losses in winter. After studying the space loads and using computational fluid dynamics (CFD) analysis it was determined that the best solution for conditioning the space efficiently was a radiant floor system using chilled and heated water with displacement ventilation providing the required outside air ventilation and supplemental cooling/heating. A radiant cooling surface allows the space temperature to be higher than traditional all-air design solutions reducing energy consumption while maintaining occupant comfort.

Heating and cooling of the apartments is provided by vertical fan coil units. The horizontal sun screen blades provide shading on the east, south and west façades and reduce the energy consumption while minimizing the technical equipment requirements and maximizing occupant comfort.

Responsible uses of appropriate technologies provide an expressive means to realize this project in a sustainable way. The use of construction waste management techniques including diverting 50 to 75% of construction waste from landfills, the use of materials locally or regionally produced and manufactured, recycled materials and wood certified products, result in a significant reduction in environmental impact. Storm water filtration systems controlled flow drainage, use of storm water for irrigation and grey water systems all contribute to water conservation and the reduction in the use of potable municipal water resulting in saved utility charges and reduced impact on natural resources.

CTBUH Initiatives

Helmut Jahn Discusses His Lifetime's Work
18 Oct 2012 – Awards Symposium Video

Videos

City-Scapes: Transformations + Interventions
11 Jun 2013 – Helmut Jahn, JAHN

Lynn S. Beedle Lifetime Achievement Award: Archi-neering Tall
18 Oct 2012 – Helmut Jahn, Murphy/Jahn

Research Papers

Lightness
Oct 2011 – CTBUH 2011 Seoul Conference

CTBUH Awards

Best Tall Building Americas 2010 Finalist
CTBUH Awards 2010


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