Wood truss construction surged in popularity in the 1960s and ’70s, but back then most buildings that used metal-plate-connected wood trusses had flat ceilings. With today’s CAD and BIM technology, however, manufacturers can create trusses for much more intricate and complicated architectural designs.
Archie Landreman, a technical director with WoodWorks, an initiative of the Wood Products Council, offers eight tips for working with metal-plate-connected wood trusses.
1. Sweat the details.
Creating a complete set of construction documents is the first no-brainer step for any wood truss project. “The more information the team has, the better job they’re going to do,” Landreman says. “You need a complete set of blueprints—architectural, structural, mechanical.”
Detailed sections, including design loads, spacing, building codes, and special shapes, are crucial for a manufacturer to properly design trusses for your project. Providing these details up front will save time and money, and the approval process will go more smoothly.
Landreman’s advice: Make sure the truss heel height isn’t overlooked during the blueprint stage. “A lot of times, plans are drawn in such a way that that particular section of the building is generic—it doesn’t necessarily show details to scale,” he says. To accurately calculate heel height, the manufacturer needs detailed information—including a drawing of a typical wall section—on wall height, height at the bottom of the header, length of the overhang, and dimensions for the soffit and fascia materials.
2. Specifications are as important as blueprints.
To design trusses properly, you must supply the manufacturer with a specification book. Such documentation may include specific carpentry information on trusses that does not appear on the project blueprints. Without a spec book, the truss manufacturer could do a complete set of truss layouts and profiles for approval, Landreman says, only to have the architect or structural engineer come back with a whole new set of drawings and specifications. “It could add a lot of time and expense for the manufacturer to have to redo something that was done without complete information,” Landreman says.
Landreman’s advice: Provide the truss manufacturer with the spec book at the time of the bid. “In some cases, it can provide a lot more detail than the blueprint itself.”
3. Get close to your manufacturer.
Before beginning a truss project, do your research on several truss manufacturers. Don’t be afraid to ask tough questions; for example, “Have you done big commercial jobs with spans in excess of 60 feet before?”
Ask truss manufacturers for their annual business volume, which can be an indicator of experience. “If someone’s manufacturing $10 million worth of trusses a year, you would think that they should have more experience and probably be able to do a better job than a manufacturer that’s doing $500,000 a year,” he says. Business volume may not always be a perfect indicator, but it’s a factor you should take into consideration.
Landreman’s advice: Ask manufacturers for references on projects similar to yours to get a sense of their experience in that area. “Not everybody has done the kind of job you’re working on,” he says.
4. Keep in touch with your manufacturer as the job progresses.
Developing a solid relationship with your truss manufacturer is important, since a good manufacturer can assist your Building Team during the early stages of the design process. If, for example, you’re designing a building with a 26-foot span for a floor truss, get the specifications details to the manufacturer, request a preliminary drawing, and work with the manufacturer’s drawing to develop a better sense of what the truss would look like and whether the manufacturer’s concept can become a reality.
Landreman’s advice: Work with the truss manufacturer to get details on span and truss height before starting any drawings to make sure the basic design concept will work before it is put on paper.
5. Make your manufacturer part of your Building Team.
When your manufacturer completes shop drawings for the placement diagrams of the trusses, getting input from all parties involved in the project should provide added perspective before final approval of these documents.
Landreman’s advice: Share manufacturer drawings with all the members of your Building Team, so that “you’re getting viewpoints from different angles.”
6. Schedule the wood truss work carefully.
The approval process can take time. To keep on schedule, leave ample time for placing the order, completing the layout and profile designs, and approving the drawings. According to Landreman, this process usually takes about two weeks, but it can vary depending on the manufacturer, the time of year, and the size and complexity of the project.
Landreman’s advice: Ask the manufacturer how long to expect the drawings to take once the purchase order or contract is placed.
7. Follow the manufacturer’s directions carefully.
The truss manufacturer should provide detailed guidelines on truss storage and installation during the approval process and upon delivery to the job site. The guidelines should include instructions on storage, lifting installation, bracing, cutting, and notching. Follow the manufacturer’s guidelines to the letter, since problems can occur if trusses are mishandled.
The chief problem is damage during delivery to the job site, as trusses are being rolled off the truck and dropped to the ground. “If they put them on a really rough part of the job site, some of the trusses could be broken or there could be damage to the connector plates when they hit the ground,” Landreman says.
Some trusses cannot be repaired once they’re put in place, so damage that goes unnoticed until after the trusses and roof sheeting are installed could result in extra time and expense to remove the sheeting and put in a new truss.
To avoid any confusion during installation, the manufacturer’s instructions should include the latest set of truss drawings showing the proper placement of all of the trusses. “Many times through the approval process some of the details in the drawings may change,” Landreman says. “If the contractor in the field doesn’t have the last revised set of truss drawings, some of those numbers and placements might have changed, and the truss could wind up in the wrong location.”
Landreman’s advice: If any instructions, warnings, or recommendations are missing, call the manufacturer immediately. “They are more than willing to get that information to you or send someone out to the site to help make sure everything’s going the way it’s supposed to.”
8. Treat floor trusses with special care.
Floor trusses can be trickier than roof trusses. “With roof trusses, there’s a tremendous amount of design flexibility, and usually you’re dealing with slope trusses,” Landreman says. With floor trusses, however, “the height of the floor truss can affect the design of the whole building, especially when you’re looking to accommodate mechanicals in those floor trusses,” he says.
For example, say you’re designing a three-story building using 24-foot floor trusses, and you expect the truss to be 12 inches deep. During the bidding process, however, the manufacturer determines that each truss needs to be 16 inches deep. “That would add a whole foot to the building height, and it’s probably not going to work,” says Landreman.
Landreman’s advice: Consult your manufacturer on truss depth and spacing when considering floor trusses for any large-scale project, rather than relying on a preprinted span table.
Related Stories
| Nov 9, 2010
Designing a library? Don’t focus on books
How do you design a library when print books are no longer its core business? Turn them into massive study halls. That’s what designers did at the University of Amsterdam, where they transformed the existing 27,000-sf library into a study center—without any visible books. About 2,000 students visit the facility daily and encounter workspaces instead of stacks.
| Nov 9, 2010
Turner Construction report: Green buildings still on the agenda
Green buildings continue to be on the agenda for real estate owners, developers, and corporate owner-occupants, according to the Turner 2010 Green Building Market Barometer. Key findings: Almost 90% of respondents said it was extremely or very likely they would incorporate energy-efficiency improvements in their new construction or renovation project, and 60% expected to incorporate improvements to water efficiency, indoor environmental quality, and green materials.
| Nov 5, 2010
New Millennium’s Gary Heasley on BIM, LEED, and the nonresidential market
Gary Heasley, president of New Millennium Building Systems, Fort Wayne, Ind., and EVP of its parent company, Steel Dynamics, Inc., tells BD+C’s Robert Cassidy about the Steel Joist Manufacturer’s westward expansion, its push to create BIM tools for its products, LEED, and the outlook for the nonresidential construction market.
| Nov 3, 2010
First of three green labs opens at Iowa State University
Designed by ZGF Architects, in association with OPN Architects, the Biorenewable Research Laboratory on the Ames campus of Iowa State University is the first of three projects completed as part of the school’s Biorenewables Complex. The 71,800-sf LEED Gold project is one of three wings that will make up the 210,000-sf complex.
| Nov 3, 2010
Park’s green education center a lesson in sustainability
The new Cantigny Outdoor Education Center, located within the 500-acre Cantigny Park in Wheaton, Ill., earned LEED Silver. Designed by DLA Architects, the 3,100-sf multipurpose center will serve patrons of the park’s golf courses, museums, and display garden, one of the largest such gardens in the Midwest.
| Nov 3, 2010
Public works complex gets eco-friendly addition
The renovation and expansion of the public works operations facility in Wilmette, Ill., including a 5,000-sf addition that houses administrative and engineering offices, locker rooms, and a lunch room/meeting room, is seeking LEED Gold certification.
| Nov 3, 2010
Sailing center sets course for energy efficiency, sustainability
The Milwaukee (Wis.) Community Sailing Center’s new facility on Lake Michigan counts a geothermal heating and cooling system among its sustainable features. The facility was designed for the nonprofit instructional sailing organization with energy efficiency and low operating costs in mind.
| Nov 3, 2010
Seattle University’s expanded library trying for LEED Gold
Pfeiffer Partners Architects, in collaboration with Mithun Architects, programmed, planned, and designed the $55 million renovation and expansion of Lemieux Library and McGoldrick Learning Commons at Seattle University. The LEED-Gold-designed facility’s green features include daylighting, sustainable and recycled materials, and a rain garden.
| Nov 3, 2010
Recreation center targets student health, earns LEED Platinum
Not only is the student recreation center at the University of Arizona, Tucson, the hub of student life but its new 54,000-sf addition is also super-green, having recently attained LEED Platinum certification.
| Nov 3, 2010
New church in Connecticut will serve a growing congregation
Tocci Building Companies will start digging next June for the Black Rock Congregational Church in Fairfield, Conn. Designed by Wiles Architects, the 103,000-sf multiuse facility will feature a 900-person worship center with tiered stadium seating, a children’s worship center, a chapel, an auditorium, a gymnasium, educational space, administrative offices, commercial kitchen, and a welcome center with library and lounge.