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Figure 1: Image of the building from the west side. Rendering by: D-Box Inc.
Designing a Green Apartment Building in New York City:
A Case Study
Rafael Pelli, Partner
Cesar Pelli & Associates, LLP, 322 8th Avenue, 18
th Floor, New York, NY 10001, 212-417-
9496, 212-414-9497 (Fax), [email protected]
1. INTRODUCTION
The design of Twenty River Terrace is presented here as a case study of the first green
residential high-rise building in New York. The project is a public-private partnership
growing out a state government initiative to advance the environmental standards for
buildings. This project has been an exciting, often frustrating, and always illuminating
opportunity to explore our deep interest in how buildings are conceived, and how changes in
building practice lead to new expressions in building design. While Twenty River Terrace has
not led to a complete re-conception of what a green high-rise residential building should be, it
has offered us a glimpse of the possibilities and the challenges that we can look forward to as
a design firm, and more broadly, as a profession.
2. CASE STUDY
2.1 Project Description
Twenty River Terrace is a twenty-seven-story glass and brick residential tower that is
currently under construction in Battery Park City, a planned residential and commercial
neighborhood bordering the west side of New York City’s financial district, directly adjacent
to the site of the former World Trade Center. Although the building was developed privately
the lease terms stipulated that this be the first building to be designed under new
environmental guidelines instituted by the Battery Park City Authority, the government
agency that has overseen Battery Park City’s development. Our challenge was to meet these
new guidelines in addition to the Authority’s pre-existing design guidelines, which govern
everything from the building materials and window proportions to the building’s orientation
and height setbacks.
2.2 Overview
Our overall goal at Twenty River Terrace was to reduce the building’s environmental impact
during construction and over its lifetime use, and increase its energy efficiency in comparison
to a traditionally constructed New York City high-rise residential building of similar size.
More specifically, we faced a complex list of sometimes conflicting criteria as we set out to
meet three separate goals: meeting the Battery Park City Authority environmental design
guidelines (a requirement), qualifying for the recently enacted New York State Green
Building Tax Credit (a financial incentive pilot program), and qualifying for a LEED Gold
rating (a voluntary national green building rating system established by the US Green
Building Council.) Considering that there were no other comparable projects to refer to, there
was a large research component to the design team’s efforts.
In meeting the environmental and energy efficiency goals, we incorporated a broad range of
strategies. Natural gas absorption chillers increase energy efficiency and reduce peak
electrical loads, and the design re-captures waste heat to provide hot water to the apartments.
Building-integrated photovoltaic cells provide five per cent of the building’s peak electrical
load. A blackwater recycling plant provides treated water for use in the toilets and cooling
tower as well as roof and park irrigation. The roofs are extensively planted using a continuous
membrane. All interior materials were selected to reduce or eliminate off-gassing, and to
maximize recycled content. Accommodations were also made for future adaptations,
including setting aside a dedicated room for a fuel cell near the electrical room. While many
of the design solutions taught us a great deal, I will focus on three specific examples: the
exterior wall, the photovoltaic cells, and materials sourcing. These three elements perhaps
best illustrate the range of issues we faced in designing this project. Some of the issues we
encountered along the way were specific to building in Battery Park City, but many are
relevant to all of us who work within the field of environmental design.
3. EXAMPLES
3.1 Exterior wall
What was most interesting for us as we developed a more thermally efficient design for the
exterior wall was the way it forced us to adapt the design process itself. The design goals
required a much larger participation by many of the technical disciplines in the early
conceptual stages of design than is typical. Alternative wall designs were analyzed not only
by the architects, but by the energy consultants for energy performance and condensation
issues, by the contractors for schedule and constructability implications, by the mechanical
engineers for systems compatibility, and by the owner for cost and payback.
Our goal with the exterior wall was to optimize its performance. We were required to be
thirty-five percent more efficient than New York State energy code. Given the pre-existing
design guidelines, as well as scheduling and budgetary considerations, we had to use a
conventional brick and concrete block wall. The challenge then was to optimize the
combined thermal performance of the masonry wall and the windows, while avoiding
condensation problems arising from the humidification of the indoor air.
Before we could begin subjecting our ideas to computer modeling, the developer
commissioned a mockup of a typical New York City masonry residential wall and tested it to
establish a baseline, especially for air infiltration. Once we had that baseline, we then began
computer simulations of many of our ideas, including different layering methods, sealant
lines, window frames, and glass to come up with the most effective and cost efficient
solutions. For example, we tested various windows and glass and found that the type of glass
was not as critical a component in the overall performance as we originally imagined. The
type of window and the frame mattered more.
Casement windows were significantly more effective than typical sliding windows in
reducing air infiltration (a major factor on a riverfront setting), while cutting solar heat gain
was not as clear a benefit as in a commercial building because in a residential building heat
gain is advantageous in winter. The insulating value of the glass was an important
consideration, but the window frames quickly emerged as greater conduits for heat loss than
any change in glass could compensate for. Many of the solutions in the final design are
relatively simple and low-cost methods of increasing efficiency that can easily be
incorporated into the way new conventional residential
high-rise masonry walls are constructed in New York City.
3.2 Photovoltaic Cells
The installation of photovoltaic cells at Twenty River Terrace served a dual purpose. These
cells, which are laminated into a piece of glass, were required to provide at peak efficiency
five percent of the base building electricity. We also saw the photovoltaics as the clearest
public expression that there were energy and environmental goals incorporated into the
building. This strategy also interested the Authority who was trying to establish precedence
for the design and building professions, to familiarize people with this new technology, and to
encourage its use in new construction.
The interesting challenge for us as design architects was how best to integrate this relatively
new building material into the composition of the exterior. We committed ourselves early on
to using the photovoltaics as an important element symbolically in the façade, but the final
design evolved considerably as were learned of their technical and cost limitations.
Because the building exposure to the south was small and often in shadow, we wanted to
locate all the photovoltaic cells on the building’s west façade where we had uninterrupted
exposure and extra reflection off the water. First, we proposed deploying them in horizontal
bands across the length of the western side. But we subsequently learned that such a design
would increase the cost of the wiring, and reduce the overall efficiency of the photovoltaics.
We finally chose to place the photovoltaics in two primary clusters. One cluster is vertically
organized on the west façade above the entrance. The second cluster is installed on the
mechanical bulkhead at the top of the building. In both cases, the photovoltaics are treated as
a special, but integral, material in the building fabric, rather than an additive component. They
serve to highlight the entry and express the technology of the overall building systems. Initial
Figure 2: Diagram showing location of photovoltaic cells with two initial alternatives
estimates suggested the photovoltaic panels would be more economical to install on the
mechanical bulkhead walls, but the final bidding resulted in the panels within the main façade
being less expensive.
Once we solved the design challenges, we discovered that it was almost impossible to bid out
this system as a standardized product. Each of the suppliers has panels that look different and
have different electrical outputs. We had no choice but to adapt our design to what we were
able to buy. Although our initial choice was to use a charcoal colored cell, we ended up with a
more efficient blue mono-crystalline cell array.
Figure 3: Regional materials used in exterior wall construction
3.3 Sourcing
Many of the decisions in this larger field of sustainable design involve the weighing of
different priorities. This requires a level of subjective preference because it is difficult to
come up with an objective measure of why one solution is better than another.
Materials sourcing was a clear example of the difficulty of coming up with an ideal solution.
We were required to purchase brick from a manufacturer within five hundred miles of the
project. In this case, the intention of sourcing materials within a radius of five hundred miles
clearly had to do with minimizing the need for transportation. Not included in the assessment
of this requirement was the relative costs of different modes of transportation and the relative
environmental impact of producing the bricks at different manufacturing plants.
We found two companies that manufactured bricks that met both the Battery Park City
Authority design guidelines and our aesthetic preferences. One company met the distance
requirement, but used an older, less energy-efficient kiln for baking the bricks and had no
access to rail transport. The other company was well beyond the five hundred mile distance
requirement, but the plant conforms to the highest international environmental standards, and
they can ship by train, which is more energy efficient than shipping by truck.
So the question becomes: Is local sourcing more energy efficient and better for the
environment? In this case we met the sourcing guidelines, but lacked the full data to measure
overall environmental impact.
Figure 4: Terrace garden on the 17th floor. Design & Rendering: Balmori Associates
4. CONCLUSION
Each of the three elements of the design of Twenty River Terrace that I have chosen to
highlight offers a glimpse of both the opportunities and challenges we face as architects in
designing sustainable architecture, particularly at a time when this industry is still in its
infancy and undergoing rapid change. The policy initiatives behind this project, and the
interest and effort demonstrated by the private building developer, suggest the possibility for a
rapid evolution of these environmental design strategies into more broadly applicable design
standards. For this to take place, though, there will need to be access to better data as a basis
for comparison, further development in some of the technologies themselves and an
adaptation by the building trades to ease the cost of implementing these solutions. Finally, the
creative challenge remains to make architecture more than the solving of an accumulation of
technical challenges. The goal of architecture must be to enrich the human experience, and the
experiential qualities of architecture rely on not only the preservation of our environment, but
on our participation in it.