By Nancy Larson Varney Ph.D., P.E., S.E., and Nathan C. Roy, P.E.

There has been a growing shift towards a holistic approach to health and wellness that considers more than just diet and exercise. As the environment can have a profound impact on our happiness, it is easy to see why students are embracing one of Brown University’s newest buildings.

Brown envisioned a building that would bring together all aspects of health and wellness from the moment students wake up. The Sternlicht Commons and Brown University Health and Wellness Center is not only the first new residence hall to open on campus in 30 years, but it also brings together the University’s Health Services, Counseling and Psychological Services, Brown Emergency Medical Services and the health promotion program bWell. Designed by William Rawn Associates, the structure is a warm, inviting composite of timber and glass that creates a relaxing, uplifting and healing space.

Choosing the Right Materials

Timber creates a calming environment that eases stress and contributes to a happier and healthier place to live and study. Paired with sunlight and floor-to-ceiling views of Pembroke Field, the result is an elevated mood and general feeling of well-being. LeMessurier, the project’s structural engineer, embraced the concept of bringing nature indoors by showcasing the building’s supporting elements.

The two buildings are joined by a glass-enclosed walkway with green spaces on either side. The North Building has three suite-style residential levels over ground-floor common spaces that include a sun-filled lounge, communal kitchen, group meeting rooms and a separate entrance lobby with bike storage. The South Building houses the University’s health and wellness spaces, including a pharmacy, ambulance bay, and bWell area on the lowest level and Health Services and Counseling and Psychological Services exam rooms and offices on the ground level. The three residential levels above offer single “pod-style” rooms with shared kitchenettes and large, open common areas. A single-story multipurpose room offers a panoramic view through three sides of full-height glass.

The ceilings of the dorm rooms and residential common spaces are cross-laminated timber (CLT) panels. Constructed of smaller boards stacked in perpendicular layers that are pressed and glued together, CLT provides significant strength, stiffness and dimensional stability. In the residential areas, CLT panels are left exposed to showcase the warmth of the timber and reduce the need for finishes. Coupled with steel framing for the gravity and lateral systems, the result is a timber-steel hybrid structure.

Structural Strategy

A steel-timber hybrid structure was selected to optimize the different structural elements. Unlike a mass timber lateral system, the steel system did not require a variance to comply with the current building code and potentially extend the construction schedule. Additionally, the first two levels of the buildings are lightweight concrete on metal deck to allow for a two-hour rated separation between residence hall and health spaces.

The design-build project, led by Shawmut Design and Construction, focused on a fast construction schedule. The use of prefabricated CLT panels increases construction speed while decreasing waste, as they are fabricated in a controlled factory, ensuring components fit together when delivered on site. The delivery of the panels is sequenced such that they can be placed straight off the truck without the need for an extensive lay-down area. Fewer crew members are needed to catch and position a panel. This process results in a solid walking surface which, coupled with fewer people on the jobsite, increases safety.

Mass Timber Considerations

CLT panels have a strong and weak direction due to the lamination layout. The layers on the top and bottom of the panels are parallel to its length and define the panel’s primarily one-way spanning direction. Nordic Structures, the CLT fabricator, provided 5-ply panels that were roughly 8 feet wide, up to 51 feet long, and with a thickness of just under 7 inches. The typical layout was three spans of approximately 15 feet each, but the CLT panels also accommodated the irregular column spacing in the South Building.

A typical CLT panel to glulam beam connection uses self-tapping screws through the panel into the beam below. At Brown, the connection between CLT panels and steel beams is similar, but the screws are installed from below through the top flange of the steel beam. Along with bracing the top flange of the beams, these connections allow the steel framing to act as drag struts to the steel-braced frames and the diaphragm chords.

Without knowing the panel layout prior to designing the steel framing, the team decided to limit the minimum beam flange to allow any beam to accommodate CLT panel joints. Additionally, limitation on columns and brace locations in the health spaces resulted in an irregular grid. The flexibility with the timber-to-steel connections helped the coordination and construction processes run smoothly.

The perimeter and corners of CLT floor plates also presented unique challenges. The curtain wall wind anchors, typically connected to steel beams or plates at concrete slab edges, were screwed into the edges, or side face, of the CLT panels. Coordination was required to comply with spacing requirements and capacity reduction values for screws installed in the side face of the panel either in the end-grain or edge-grain laminations were considered.

Mass Timber Benefits

There are reasons a project team might consider mass timber construction beyond the benefits of visually exposing the timber structure. Two of the primary positive impacts of incorporating timber are related to resilience and sustainability. From supporting managed forestry, being a renewable resource, and sequestering carbon, timber construction offers many green benefits.

A recent focus on reducing embodied carbon of structures is reflected in the SE 2050 Commitment Program (SE 2050) of the American Society of Civil Engineers (ASCE).

Add all the other pieces to complete construction and this steel and timber skeleton becomes a building that reaps the biophilic benefits of wood for residents and visitors alike. The connection to nature can be seen in the reflection of trees on the glass wall of the multipurpose room and the illumination of the CLT ceilings in the common spaces of the residence halls.

Project Team

• Architect: William Rawn Associates, Architects
• Structural Engineer: LeMessurier
• Contractor: Shawmut Design & Construction
• Steel Fabricator: Ocean Steel & Construction
• CLT Fabricator: Nordic Structures
• Concrete Contractor: Marguerite Concrete Contractors

Ausutors:

Nancy Larson Varney, Ph.D., P.E., S.E., is an associate teaching professor at Northeastern University, formerly an associate with LeMessurier. She can be reached at n.varney@northeastern.edu.

Nathan C. Roy, P.E., is a principal with LeMessurier. He can be reached at nroy@lemessurier.com.

The post Glass and Timber Reflect the Outdoors Within at Brown University Health and Wellness Center appeared first on ĐÓ°ÉÔ­°ćŇ•îl.

The post Glass and Timber Reflect the Outdoors Within at Brown University Health and Wellness Center appeared first on ĐÓ°ÉÔ­°ćŇ•îl.

BABSON PARK, Mass. –– Windover Construction, an award-winning construction management firm specializing in academic building, recently completed construction of the Weissman Foundry at Babson College.

The 10,000-square-foot building is Babson’s newest and most innovative academic center. 

The Weissman Foundry is an open-door design studio inspiring transdisciplinary innovative collaboration between Babson, Olin and Wellesley students for the advancement of new or existing projects. It was made for the curious — the entrepreneurs, engineers, artists, and academics alike. Designed as an intentional mashup of student interests, the Weissman Foundry is meant to ignite forward-thinking idea exploration, iteration, and design, and to facilitate meaningful knowledge transfer between the three college communities.

ĐÓ°ÉÔ­°ćŇ•îl spoke with Randy Catlin, EVP & COO of Windover Construction, to discuss the project.

Q: When did construction begin and when was it completed? Architectural firm/general contractor?ĚýĚý

Catlin: Construction began in January of 2018 and was completed in August of 2018.

Builder:
Mechanical Engineer:
Architect:
Structural Engineer:

Q: What was the overall goal of this construction project?
Catlin: The overall goal of this project was to create a 10,000-square-foot open-door design studio to inspire transdisciplinary innovative collaboration between Babson, Olin, and Wellesley college students for the advancement of new or existing projects! It was made for the curious—the entrepreneurs, engineers, artists, and academics alike. Designed as an intentional mashup of student interests, the Weissman Foundry is meant to ignite forward-thinking idea exploration, iteration, and design, and to facilitate meaningful knowledge transfer between the three college communities.

Windover led the preconstruction and construction and collaborated with the design team to execute Babson’s vision for the advanced facility. Featuring areas for project work, large and small, this new creative space provides access to workbenches, advanced fabrication equipment, traditional tools, robotics, AR/VR, and sought-after connections to expertise and training.

Q: What are the major design elements/features? (Sustainable, if any?) How will this design influence/improve the student learning/teaching environment? 

Catlin: The facility features several complex and contemporary design elements. With meticulous upfront preconstruction planning, Windover prepared for the successful build of these elements despite facing a condensed, eight-month construction schedule. The stunning building envelope, consisting of the convergence of curtainwall, masonry, and metal panel at every elevation with dramatic wood canopies, required tight coordination across multiple trades to execute.

Interiorly, the space features polished concrete floors, open and connected spaces divided by louver-operated doors, wood slat ceiling accents, exposed ductwork, and moveable furniture, fixtures, and worksurfaces all contributing to the flexibility and utility of the space. As the name “Foundry” suggests, it is an industrial concept tempered by contemporary, stunning design features.

Set within a wooded landscape, the industrial-looking Foundry has abundant natural light, wood canopies, and a “living roof” that supports the college’s sustainability commitment and is registered with the certification goal of LEED® Silver. The facility also incorporates high-performance MEP systems, including a custom energy recovery unit.

Through these unique design elements, students and teachers alike enjoy a versatile and open environment that ignites forward-thinking idea exploration, iteration, and design, and knowledge transfer. The Foundry is a place for learning and hands-on experimentation.

Q: How does this project follow other national school construction trends? What is unique about this project compared to other school construction trends? 

Catlin: For many years now, the trend of experiential and transdisciplinary education has continued to grow and shape the way academic campuses are looking at their academic buildings and spaces. Learning environments are becoming more flexible, adaptable and integrated in response to this trend with buildings dedicated to STEM, STEAM, and STREM curriculums. With a focus on hands-on and collaborative learning, traditional classrooms are transforming into open-concept spaces with moveable furniture and makerspaces, and academic buildings are now being designed and programmed to host multiple disciplines under one roof.

Unlike STEM, STEAM, and STREAM buildings which are dedicated to select disciplines, the Weissman Foundry was intentionally designed to support a mash-up of student interests and a diverse spectrum of entrepreneurs, artists, engineers, and academics alike. Through experiential and transdisciplinary approaches, the Foundry is a place that equips students to use their collective business, engineering, and liberal arts educations to create impactful social and economic value everywhere.

Q: Are there any innovative technological/electronic systems or solutions integrated into this new facility?

Caitlin: Yes. Due to the unique industrial and open design, Windover facilitated the intricate MEP/HVAC infrastructure, including moveable fixtures, high power loads, and complex ductwork connections. All of this was made possible by using 3D BIM coordination and prefabrication of selected elements.

The post Q&A: Windover Construction Completes Babson College’s New Academic Center appeared first on ĐÓ°ÉÔ­°ćŇ•îl.

The post Q&A: Windover Construction Completes Babson College’s New Academic Center appeared first on ĐÓ°ÉÔ­°ćŇ•îl.