flexiblefullpage
billboard
interstitial1
catfish1
Currently Reading

Small but mighty: Berkeley public library’s net-zero gem

Small but mighty: Berkeley public library’s net-zero gem

The Building Team for Berkeley, Calif.’s new 9,500-sf West Branch library aims to achieve net-zero—and possibly net-positive—energy performance with the help of clever passive design techniques.


By David Barista, Editor-in-Chief | March 27, 2013
Due to open in August 2013, the West Branch library in Berkeley, Calif., replace
Due to open in August 2013, the West Branch library in Berkeley, Calif., replaces a branch library building formerly located on the site. Its net-zero energy and carbon-neutral design scheme was crucial to getting the $5.5 million, 9,500-sf replacement project approved by the city board.
This article first appeared in the BD+C April 2013 issue of BD+C.

Situated on a tiny, quarter-acre lot along bustling University Avenue, Berkeley, Calif.’s, new West Branch library may not be large in stature, but it’s one of the most significant library projects of the year.

Due to open in August, the 9,500-sf facility will join a handful of libraries across the country that are net-zero energy performers. And, if all goes as planned, the facility will achieve net-positive energy performance—supplying power back to the city’s electrical grid—and have a carbon-neutral footprint.

The project’s Building Team, led by Harley Ellis Devereaux’s GreenWorks Studio (www.harleyellisdevereaux.com), is targeting LEED Platinum. The $5.5 million library is one of the first projects to take part in the California Public Utility Commission’s ZNE Energy Pilot Program, supported by the Pacific Gas and Electric Co.

Michael Bulander, LEED AP BD+C, Associate with Harley Ellis Devereaux, says the PG&E partnership was critical to achieving NZE performance on the West Branch project. The utility subsidized early computer modeling work, including computational fluid dynamics analysis of ventilation schemes and a solar axis study for the rooftop solar installations.

The latter was especially tricky, says Bulander, due to the project’s tight urban site. “The starting point for the entire design was actually the building’s roof,” he says. “Because taller buildings surround the tiny site—including a three-story hotel next door—the team had to determine the optimal roof configuration for accommodating as many PV and solar thermal panels as possible, and for minimizing shading from the other buildings.”

Projected Energy Performance

Renewable energy generation
Photovoltaic panels    15.4 kBtu/sf/year
Solar thermal panels    2.0 kBtu/sf/year
Total power generation    17.4 kBtu/sf/year

Building electrical load
Lighting    3.8 kBtu/sf/year
Heating    3.5 kBtu/sf/year
Cooling (heat pumps)    2.2 kBtu/sf/year
Plug load    6.3 kBtu/sf/year
Hot water    0.9 kBtu/sf/year
Ventilation fans    0.7 kBtu/sf/year
Total power load    17.4 kBtu/sf/year

Net energy consumption    0.0 kBtu/sf/year

The rooftop solar panels also had to compete for space with three rows of skylights that were instrumental to the building’s daylighting scheme. And, of course, the roof configuration had to meet the programmatic requirements for the library.

“It was a real balancing act,” says Gerard Lee, AIA, LEED AP, Associate and Project Manager with Harley Ellis Devereaux. “We had to find the sweet spot between what the building wanted to be from a program standpoint and what it should be from an energy-performance standpoint.”

Through modeling, the design team determined that the optimal design consisted of a compact, rectangular roof, 24 feet high. The solar panels are oriented horizontally, stacked three high at a 20-degree angle to maximize solar collection throughout the year. Four PV arrays are interspersed between three rows of skylights. A total of 120 panels will generate 75,050 kWh/year with a final system efficiency of 93.8%. The 16 solar thermal panels are located in two arrays at the northeast corner of the roof.

“The design takes into consideration the skylight locations and heights,” says Lee. “The PV panels are angled and located to avoid casting shadows on the skylights, and the same can be said for the skylights.”

 

The team modeled the design to maximize the number of solar panels that could be installed on the compact roof. The photovoltaic and solar thermal panels were situated so as not to interfere with the three rows of skylights.

 

Once the roof design scheme was established and the team could accurately calculate the amount of solar energy that would be harvested, they went about designing the building to minimize the energy use intensity to match the renewable energy supply.

“Our EUI is very low in relation to other projects—just 17 kBtu/sf/year,” says Bulander. For comparison, the average office building has a EUI of 193; hospitals can exceed 500.

Passive design requires careful modeling, detailing

Passive design strategies like natural ventilation, radiant heating/cooling, and daylighting helped meet the aggressive energy goals. Prevailing winds off the Bay made natural ventilation a logical approach, but the site proved problematic yet again. Because the building is located in a high-traffic area next to a stoplight, placing operable windows in the main façade was not feasible. “Trucks often wait at the red light in front of the building,” says Bulander. “We needed to block that out.”

 

To minimize energy consumption in the building, the design scheme utilizes daylighting through a series of skylights and a large glass curtain wall on the main façade. Where possible, the team minimized the amount of electrical lighting in the building, such as in the back office areas. When the library closes for the day, the entire facility will essentially go dark to reduce energy use.

 

With the help of CFD modeling, the design team devised a clever natural ventilation scheme that uses negative pressure to pull in fresh air at the rear of the building and then circulate it through the interior spaces.

“We’re essentially using the steady wind that is blowing over the top of the front façade to create a negative pressure that pulls the air through the building,” says Lee. A series of louvers and ventilation fans at the roof level will exhaust the warm air as needed, and radiant flooring will provide supplemental heating and cooling. A building automation system will monitor and control the entire process, ensuring that the interior climate remains comfortable for the staff and patrons.

“We’re trying to make the facility as automated and foolproof as possible,” says Lee. He says the BAS will allow staff to override certain settings—such as closing an operable window on an unusually windy day—but it will automatically revert to its programmed settings at the end of the day. “For the most part, it’s a very intelligent building that needs very little interference from the librarians and staffers.”

As with any net-zero building project, plug loads are a major concern for the Building Team. Library patrons will notice a dearth of outlets in the new facility. This is meant to minimize the number of people who plug in their energy-gobbling laptops, smart phones, and tablets. The library will offer free computer and Internet access for visitors, but in lieu of desktops that are plugged in all day, users will be able to check out fully charged laptops. A charging station will allow the staff to track and control the amount of energy being consumed by the computers.

Lee and Bulander are fully confident that the library staff and patrons will embrace the resource conservation efforts. A building performance dashboard will greet all visitors at the main entrance, providing a real-time snapshot of the building’s energy production and energy/water consumption.

“We’re taking advantage of the ‘Prius effect,’” says Bulander. “When you see a display showing how much energy and water you’re using, you feel more involved in trying to minimize it. It becomes a game.”

The building’s natural ventilation scheme involves pulling in outdoor air from the rear of the building and circulating it throughout the interior spaces. A series of louvers and fans at the roof level will exhaust the air as needed.

 

PROJECT SUMMARY

Berkeley Public Library – West Branch
Berkeley, Calif.


BUILDING TEAM
Client: City of Berkeley, Calif.
Architect, sustainability consultant, commissioning agent: Harley Ellis Devereaux, GreenWorks Studio
General contractor: West Bay Builders
MEP engineer: Harley Ellis Devereaux
Structural engineer: Tipping Mar
Civil engineer: Moran Engineering
Landscape architect: John Northmore Roberts and Associates
Cost estimator: Cumming Corp.

GENERAL INFORMATION
Size: 9,500 sf
Cost: $5.5 million (est.)
Completion: August 2013

Related Stories

Architects | Nov 9, 2021

Download BD+C’s 2021 Design Innovation Report

AEC and development firms share where new ideas come from, and what makes them click.

Architects | Nov 9, 2021

Download BD+C’s 10 Predictions for the Construction Industry in 2022

Our prognostications focus on how AEC firms will streamline and modernize their projects and operations.

Architects | Nov 9, 2021

Pelli Clarke Pelli Architects announces renaming

Founded by Cesar Pelli with partners Fred Clarke and Diana Balmori in 1977, the firm began its legacy as Cesar Pelli & Associates at its first office in New Haven, Connecticut.

Architects | Nov 2, 2021

What rugby can teach us about designing the workspace of the future

Two veteran workplace designers offer a sports-based analogy for designing agile spaces to meet the needs of an evolving workforce.

Adaptive Reuse | Nov 1, 2021

CallisonRTKL explores converting decommissioned cruise ships for housing

The rapid increase in cruise ship decommissioning during the last 18 months has created a unique opportunity to innovate and adapt these large ships.

Sustainability | Oct 28, 2021

Reducing embodied carbon in construction, with sustainability leader Sarah King

Sustainability leader Sarah King explains how developers and contractors can use the new EC3 software tool to reduce embodied carbon in their buildings.

Cladding and Facade Systems | Oct 26, 2021

14 projects recognized by DOE for high-performance building envelope design

The inaugural class of DOE’s Better Buildings Building Envelope Campaign includes a medical office building that uses hybrid vacuum-insulated glass and a net-zero concrete-and-timber community center.

AEC Tech | Oct 25, 2021

Token Future: Will NFTs revolutionize the design industry?

How could non-fungible tokens (NFTs) change the way we value design? Woods Bagot architect Jet Geaghan weighs risk vs. reward in six compelling outcomes.

Giants 400 | Oct 22, 2021

2021 Retail Giants: Top architecture, engineering, and construction firms in the U.S. retail building sector

Gensler, CallisonRTKL, Kimley-Horn, and Whiting-Turner top BD+C's rankings of the nation's largest retail sector architecture, engineering, and construction firms, as reported in the 2021 Giants 400 Report.

boombox1
boombox2
native1

More In Category


Urban Planning

Bridging the gap: How early architect involvement can revolutionize a city’s capital improvement plans

Capital Improvement Plans (CIPs) typically span three to five years and outline future city projects and their costs. While they set the stage, the design and construction of these projects often extend beyond the CIP window, leading to a disconnect between the initial budget and evolving project scope. This can result in financial shortfalls, forcing cities to cut back on critical project features.



Libraries

Reasons to reinvent the Midcentury academic library

DLR Group's Interior Design Leader Gretchen Holy, Assoc. IIDA, shares the idea that a designer's responsibility to embrace a library’s history, respect its past, and create an environment that will serve student populations for the next 100 years.

halfpage1

Most Popular Content

  1. 2021 Giants 400 Report
  2. Top 150 Architecture Firms for 2019
  3. 13 projects that represent the future of affordable housing
  4. Sagrada Familia completion date pushed back due to coronavirus
  5. Top 160 Architecture Firms 2021