In New York City these days, residential towers cannot be
too slim or too tall. The improbably slender form of One57, now fully enclosed,
is the furthest along of a new crop of super-thin, supertall, super-luxe
residential towers. Designed by Atelier Christian de Portzamparc for Extell
Development Company, with glass panels of blue, pewter, and silver, it rises
1,004 feet, hundreds higher than even its tallest neighbors.
Just blocks away, CIM Group and Macklowe Properties' 432
Park Avenue will top out at even greater height, 1,396 feet. The square floor
plan, extruded without setbacks in concrete with punched windows, has reached
about 45 stories. It is as proportionally pristine as a Sol LeWitt sculpture—an
image of “pure strength,” says its architect, Rafael Viñoly. Nearby, SHoP
Architects is still refining its design for the 1,350-foot-tall building
planned for 111 West 57th Street. So far, it is the slimmest of about a dozen
super-skinny, supertall towers planned or under construction in New York. The
ultrathin buildings are intended to lure buyers willing to plunk down as much
as $95 million for a home perched high in the sky.
“These towers are going up in neighborhoods that are
distinctive and have tall-building zoning capacity yet have only small parcels
available,” says Carol Willis, the founder of New York's Skyscraper Museum.
“Evolving technology and unprecedented price points make these buildings work,”
she says. Though super-slims are for now unique to just a few Manhattan
neighborhoods, high-rise living worldwide will benefit from the innovations
that make these super-slims possible.
Codes define a slender building as one that is more than seven
times as high as the narrowest side at its base. In the Skyscraper Museum's
recent show Sky High and the Logic of Luxury, Willis exhibited towers she calls
super-slender—those with at least a 1:12 ratio. The slenderness ratio of 111
West 57th is a startling 1:24.
Zoning Sculpts Form
Regulatory requirements, especially zoning, substantially
influence the design of the super-slims. Several will rise in a special Midtown
Zoning district that permits high density and the transfer of “air
rights”—subtracting unused development square footage from atop existing
buildings and adding it to a new tower. All of the super-slims involve such
transfers. And even though their assertive profiles on the skyline and the
shadows they will cast have sparked protests, most are being built “as of
right.” In other words, they are on sites that lack height limits and do not
require additional zoning or design review.
Not all of the city's ultra-skinny towers are being built in
Midtown Manhattan. An 830-foot-tall, 57-story tower with a slenderness ration
of 1:11 is under construction at 56 Leonard Street in the TriBeCa neighborhood.
The building, designed by Herzog & de Meuron, will have floors
cantilevering as much as 25 feet, creating the impression that they are precariously
stacked. It will be able to grow so much taller than its mostly low-rise
neighbors because Alexico Group, the project's co-developer with Hines,
acquired air rights from the entire block.
In most parts of the city, towers must not penetrate the
“sky exposure plane,” which defines a buildable envelope that slopes away from
the street, to permit sun access. For 53 West 53rd Street—a 1,050-foot-tall
hotel and condo tower soon to begin construction next to the Museum of Modern
Art (MoMA)—architect Jean Nouvel tapers the building's spire to fit within a
pair of sky exposure planes converging from two streets. Similarly, 432 Park
Avenue confines itself to the zoning envelope by rising from the center of the
through-block site without setbacks.
At 111 West 57th Street, SHoP has opted to move its tower
away from the street in order to stay within the permitted envelope while
minimizing required setbacks. As part of an agreement with the city's Landmarks
Preservation Commission, the tower will rise from the courtyard of Warren and
Wetmore's 1925 Steinway office building, which will be turned into apartments
as part of the project. The new tower's highest floors must still be set back,
but SHoP makes the most of the requirement, creating an expressive stepped crown.
Bronze window mullions turn into finials to visually dissolve the top of the
building into the sky. “We wanted to make a New York City building, so we
worked with the zoning to express the dictated setbacks yet take it further,”
says SHoP partner Chris Sharples.
Structure and
Stiffness
Addressing the unique structural aspects of ultra-slender
towers without sacrificing too much sellable space to elevators, stairs,
columns, and shear walls is the key challenge, explains Silvian Marcus, the
director of building structures at WSP. The firm is the structural engineer for
most of Manhattan's super-slims.
According to Marcus, high-strength concrete (around 14,000
psi) is essential in slender towers. Concrete mixes have improved a great deal
in recent years, he says, with additives enhancing workability. Fly ash, a
byproduct of coal combustion, is increasingly used to replace a large portion
of Portland cement in these mixes, because it offers strength without the
substantial heat normally generated during cement-curing, which can cause
cracking. (It also reduces the landfilling of the ash, which can contaminate
surroundings.)
Surprisingly, wind loads are not as much of a design
challenge as the oscillations those forces induce are. Building codes dictate
stiffness to protect occupants and avoid distortions that crack windows or
cause leaks, but codes do not require steps to counter the discomfort people
feel when sway acceleration is too great (measured in fractions of g-force, or
milli-gs). Such discomfort may sound trivial, but Marcus says minimizing
acceleration is essential to habitability. WSP designs to approximately 18
milli-gs for winds that would be encountered over a 10-year period and as
little as 5 milli-gs for more frequent low-velocity winds. That standard
dictates a host of responses that affect building mass, structural
configuration, and whether dampening devices are needed.
Core Principles
The simplest tactic to combat those forces is to add weight,
especially at the top of the building, but Marcus says that's just a first
step. The engineer must engage the building's entire structural system by
strengthening the connection of the core to the perimeter columns and shear
walls. To stiffen 111 West 57th Street, WSP thickened the shear walls that run
the full length of the east and west exterior walls to as much as 3 feet, and
linked them to the core with deep beams.
The building's 15½-foot floor-to-floor heights left plenty
of space above the ceilings to conceal the stiffening beams. The dimension not
only suited the engineer's purpose: the floor-to-floor height also coincides
with the maximum code-permitted run of the exit stairs. That allows the floor
space given over to the core to be minimized, especially as the two required
exit routes are nested atop each other in a “scissor” configuration. The
generosity of the resulting 12-foot-high finished ceiling has become a selling
point.
Marcus varies core-and-perimeter tactics to suit the
architectural intention of each building. The exterior of Viñoly's 432 Park
Avenue is structural poured-in-place concrete that acts as a tube. (With white
cement and careful attention to forming, the tube is also the finished
architectural surface.) Even with monumental 10-foot-square windows, the tube
is stiff enough to permit a 30-foot column-free zone between the exterior and
the central core.
At 53 West 53rd Street, Nouvel aligns the elevators and
stairs along the west wall, where the building abuts an office tower. Marcus
says the structure “relies very little on the core” because of the extremely
stiff concrete diagrid exterior that slopes to a pinnacle at 1,050 feet. The
floor layout leaves a large unimpeded area for MoMA galleries at the base.
At 56 Leonard, WSP stiffens the structure by placing the
core's perimeter wall outside the hallway that wraps the elevators and stairs.
Enlarging the core increased the building's rigidity enough to minimize
interior columns. As the building rises, the outer core wall vanishes. Shear
walls wrap mechanical floors to further stiffen the building. They are set back
3 feet from the perimeter, behind a glass-louver facade.
Despite their prominence, the Leonard Street building's
cantilevers neither contribute nor detract from the stiffness of the tower.
Marcus calls them a “local problem” structurally, handled in a number of ways,
with exposed, varying floor-slab thicknesses expressing the forces they resist.
In full-floor cantilevers, short walls within the building envelope and columns
at the far edge of the cantilever lock top and bottom slab together to attain
rigidity without diagonal braces. They are essentially Vierendeel trusses, say
the designers.
Confusing the Wind
Buildings with a slenderness ratio of 1:10 or more demand
additional steps to reduce acceleration, such as dampers installed near their
crowns. At One57 and 432 Park these take the form of tuned mass dampers, which
consist of weights (typically between 500 and 1,200 tons) suspended from
springs. Some buildings, including 56 Leonard, rely on a tuned liquid damper.
It has a compartmentalized pool filled with water. In both types, the mass
moves more slowly than the building sways, dampening the acceleration.
Marcus also slows accelerations by reducing wind forces on
the buildings. The setbacks at 111 57th “confuse” the wind, reducing pushing
forces on the windward side and the suction forces on the leeward side. As the
design is refined, the architect will probably include gaps in the facade to
let wind pass through the building, lowering the overall force.
Viñoly provides unenclosed floors at intervals up 432 Park
Avenue's facades. The spaces between columns let the wind pass, and also offer
Marcus the opportunity to conceal stiffening columns and beams that cannot be
accommodated on occupied floors. A curved enclosure protects the core and
mechanical equipment.
Commercial towers have, until now, led tall-building
innovation. But as more skyscrapers house residential uses, including luxury
hotels, the building type's appeal will push architects and engineers toward
further collaborative refinement and innovation. “We are in a continuous search
for improving materials and systems,” Marcus says. “To reach higher into the
sky, we take small steps.”
James S. Russell, FAIA, is a New York–based architecture
critic and journalist. He is author of the book The Agile City: Building
Well-being and Wealth in an Era of Climate Change.
Source: Architectural
Record
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