In all climate zones, the various forms of metal cladding—single-skin panels, metal composite materials (MCM) panels, and insulated metal panels (IMPs)—are proving to be reliable, durable elements on more and more office buildings, hospitals, multifamily housing, industrial structures, and other commercial and institutional projects. Single-skin metal panels and metal composite panels, whether in the form of aluminum, steel, zinc, or copper, enable designers to create clean, smooth, crisp lines on exterior walls that can lend a sleek, contemporary look to any structure. Similarly, IMP products offer multiple metals, finishes, and profiles with an extensive color palette, providing designers a wide variety of aesthetic options as well as enhanced thermal performance.
Building Design+Construction spoke with building enclosure specialists and technical experts at manufacturing companies to get their insights into how Building Teams can best use metal cladding panel systems. In recent years, building enclosure experts have gained more confidence in the ability of metal cladding products to stand up to the elements and protect the building envelope. Like any cladding material, however, each type of metal panel system comes with specific attributes, requirements, and limitations that Building Teams must be aware of.
The potential difficult areas include:
• Preventing moisture penetration
• Ensuring that joints are designed correctly
• Addressing hurricane resistance codes along coastal areas
• Paying special attention to how metal cladding interfaces with windows, doors, and other cladding material
But first, let’s get down to the fundamentals.
THE BASICS OF METAL CLADDING
Metal cladding comes in many different dimensions and thicknesses, and can be custom fabricated for individual projects:
• Single-skin metal panels are available in both concealed fastener and exposed fastener varieties.
• Metal composite materials panels consist of two sheets—most often aluminum or steel—bonded to a polyethylene core. These panels are fabricated into panels using perimeter extrusions to create attachment and joinery systems.
• Insulated metal panels consist of a layer of rigid foam core insulation sandwiched between two pieces of sheet metal. These metal panels are manufactured either as a foamed-in-place system or laminated with board stock foam and can be up to six inches in thickness. Insulation values for IMP panels are available from R-10 to R-45, and in some cases as much as R-48.
Typically, most architectural applications for commercial and institutional buildings are applied to metal stud framing or structural tube supports, depending on the manufacturer’s recommendation. Concealed fastener and insulated metal panels typically attach to each other via a tongue-in-groove joint. For industrial applications, such as warehouses or industrial plants, metal panels are fastened to steel Z girts and include thermal breaks.
BARRIER WALLS AND RAINSCREEN WALLS
There are two basic types of fabricated metal panel systems: barrier walls and rainscreen walls. Barrier walls attempt to keep all rainwater from penetrating the outer face of the exterior walls. All panel joints are sealed by butyl, gaskets, or silicone sealant, applied either within the joints or to the face of the joint. The joinery seals expand and contract as needed to accommodate temperature variations and building movement. These seals, along with the factory-built panels that include air and moisture barriers, provide a high-performance exterior envelope with a low air infiltration rate; in some cases the air exchange per hour is as low as 0.043, depending on the building and climate zone. This allows IMPs to meet the “continuous insulation,” or “ci,” requirements of ASHRAE 90.1.
In contrast to a barrier wall, an effective rainscreen system allows some water to penetrate through the panel joinery. Inside the wall cavity, a weather barrier provides a drainage plane for the water to drain out of the cavity. A variation of this design is the pressure-equalized rainscreen system, which provides air vents for each panel to equalize pressure between the outside and inside of the systems. This design aims to prevent water droplets from being driven through the panel joints because wind pressure acting on the outer face of the panel is equalized in the cavity.
When properly installed, there should be no significant pressure differential to drive rain through joints. During extreme weather, a small amount of water may penetrate the outer cladding; it should run down the back of the cladding sheets as droplets and be dissipated through evaporation and drainage.
EXTRA: 8 Helpful Tips from Metal Cladding Manufacturers |
Joinery systems between panels must be properly designed to accommodate thermal expansion and differential movements between panels. Narrower joints can have more difficult tolerances to meet in the field because smaller variations in the placement of panel joints may be more noticeable to the eye than the same amount of variation in a wider joint, according to Rob Kistler, AIA, a principal with The Facade Group LLC, Portland, Ore. That’s because an eighth-inch variation in a quarter-inch joint looks bigger in proportion to an eighth-inch variation in a half-inch joint.
If an open-joint rainscreen system is improperly designed or installed, it might let in more rain than it is designed to accommodate. “The wind-driven rain could go right through and strike the weather barrier,” Kistler says. “You want to make sure that you block the horizontal rain. If there’s any kind of a hole in the membrane, with water shedding down it, the water is going to find the hole.” That could result in water infiltration into the building.
A key part of a successful open-joint rainscreen panel design is the drainage plane behind the cladding, says Linda McGowan, PE, AIA, president and principal with Building Consultants & Engineers, Littleton, Colo. “You have to make sure that the moisture that gets behind the cladding is able to drain—that it has a reasonable means of getting out from behind the metal panel system,” she says. The width of the air gap between the cladding and the structural frame is a key factor for proper drainage, providing adequate pressure equalization, and enabling the weather barrier to dry after exposure to moisture.
“There is always going to be something that is going to interrupt the drainage plane,” McGowan adds. “You need to understand that and provide reasonable accommodation.” Areas of particular concern: behind heads of windows, heads of doors, and the points where the panels are attached to the structure. Water that encounters those points needs to have a drainage pathway.
The bottom line is that with proper design and a qualified, experienced installer, the chances of significant water intrusion occurring in an open-joint rainscreen system can be greatly reduced.
HOW TO IMPROVE WATER TIGHTNESS
Water tightness is a relative standard depending on the application. On a single-story industrial building, for example, some water intrusion may be acceptable. If a small amount of water penetrates the cladding and ends up on the edges of a concrete shop floor where it can quickly dry, it may be an acceptable outcome.
In regions of the country where the possibility of water intrusion is a major concern, designers should create a mockup of a section of cladding and test it for water penetration, says building enclosure consultant Richard Keleher, AIA, CSI, LEED AP, of Concord, Mass. The American Architectural Manufacturing Association 508-07 test for pressure-equalized rainscreen systems includes a cyclic check for rapid pressure equalization, a static water test, and a dynamic water test that employs an aircraft engine to blow water at a section of panel constructed to emulate the finished product. The AAMA 508-07 test allows water (usually mist) to contact up to 5% of the air/water barrier, with no damming or streaming, to earn a pass rating. To get accurate results, you have to ensure that the mockup test is designed to the 508 test specifications, making sure the corners of the test section are airtight and watertight, Keleher adds.
EXTRA: Checklist of Best Practices for Metal Panel Projects |
Another test manufacturers can use for rainscreens is AAMA 509-09, which provides ratings for water intrusion (W) and ventilation (V), according to Rick Brow, marketing director for Centria Architectural Systems, Moon Township, Pa. “The desired effect is to have minimal water and high ventilation to dry the cavity,” says Brow, author of the manual Advanced Thermal and Moisture Protection. A rating of W1 (equivalent to one ounce or less of water penetration in 15 minutes) and V4 (6-8 cfm/sf in 15 minutes) would be “a highly effective result.” The W1 rating is basically the same as the rating achieved with AAMA 508, says Brow.
For barrier walls, the appropriate weather tightness tests are ASTM E 331 (water infiltration), ASTM E 283 (air leakage), and AAMA 501.1 (dynamic water pressure), according to Doug Pickens, VP of sales and marketing, Metl-Span, Lewisville, Texas.
WATCH YOUR WINDOWS TO AVOID PROBLEMS WITH THERMAL BRIDGING
All building cladding systems have some degree of thermal bridging. Thermal bridging can occur at fastener locations, joints, and intersections with other materials. Reducing the number of fasteners, joints, and penetrations, combined with careful detailing, can minimize the effects of thermal bridging in metal panel wall assemblies. Providing insulation outside the support framing system is also recommended to help minimize thermal bridging.
The concept of a continuous thermal barrier was originally recommended in the 2001 Massachusetts Energy Code. This more stringent continuous insulation, or “ci,” code requirement is likely to become more common in other states, given the trend toward more energy-efficient structures.
Thermal gain and loss from fenestration systems should be of much greater concern to Building Teams than thermal bridging. In the case of structures with many windows, it is important to invest in high-efficiency windows as well as the appropriate metal cladding material in order to make the building envelope as energy efficient as possible.
The metal panel industry is continuing to study how its products can contribute more to the greening of the built environment. One of metal cladding’s green characteristics is the ability to be recycled after its lifespan expires. The technology has already won over building enclosure specialists, and as building science advances, metal panel systems, insulation, and air and vapor barrier solutions will continue to be improved. Odds are that metal panel systems—with their many advantages—will become an even more popular cladding choice in the years to come.
Related Stories
Sponsored | Building Enclosure Systems | May 16, 2023
4 steps to a better building enclosure
Dividing the outside environment from the interior, the building enclosure is one of the most important parts of the structure. The enclosure not only defines the building’s aesthetic, but also protects occupants from the elements and facilitates a comfortable, controlled climate. With dozens of components comprising the exterior assemblies, from foundation to cladding to roof, figuring out which concerns to address first can be daunting.
Multifamily Housing | May 16, 2023
Legislators aim to make office-to-housing conversions easier
Lawmakers around the country are looking for ways to spur conversions of office space to residential use.cSuch projects come with challenges such as inadequate plumbing, not enough exterior-facing windows, and footprints that don’t easily lend themselves to residential use. These conditions raise the cost for developers.
Headquarters | May 16, 2023
Workplace HQ for party clothing company Shinesty celebrates its bold, whimsical products
The new Denver headquarters for Shinesty, a party clothing company, was designed to match the brand’s fun image with an iconic array of colors, textures, and prints curated by the design agency, Maximalist. Shinesty’s mission, to challenge the world to live more freely and “take itself less seriously,” is embodied throughout the office interior.
Office Buildings | May 15, 2023
Sixteen-story office tower will use 40% less energy than an average NYC office building
This month marks the completion of a new 16-story office tower that is being promoted as New York City’s most sustainable office structure. That boast is backed by an innovative HVAC system that features geothermal wells, dedicated outdoor air system (DOAS) units, radiant heating and cooling, and a sophisticated control system to ensure that the elements work optimally together.
Life of an Architect Podcast | May 15, 2023
Life of an Architect Podcast Ep. 125: What Makes a Great Employee?
How do you define a great employee? The answer is most likely dependent on who is attempting to respond: the employee or the employer. Life of an Architect's Bob Borson, FAIA, and Andrew Hawkins, AIA, talk about the traits and characteristics of great employees.
K-12 Schools | May 12, 2023
In Virginia, a new high school building helps reimagine the experience for 1,600 students
In Virginia, the City of Alexandria recently celebrated the topping out of a new building for Alexandria City High School. When complete in 2025, the high-performance structure will accommodate 1,600 students.
University Buildings | May 11, 2023
New ‘bold and twisting’ building consolidates School of Continuing Studies at York University
The design of a new building that consolidates York University’s School of Continuing Studies into one location is a new architectural landmark at the Toronto school’s Keele Campus. “The design is emblematic of the school’s identity and culture, which is centered around accelerated professional growth in the face of a continuously evolving labor market,” according to a news release from Perkins&Will.
Sustainability | May 11, 2023
Let's build toward a circular economy
Eric Corey Freed, Director of Sustainability, CannonDesign, discusses the values of well-designed, regenerative buildings.
Hotel Facilities | May 9, 2023
A new camping destination near Utah’s Zion National Park offers a variety of all-season lodgings and amenities
Outdoor lodging brand AutoCamp has opened a new camping destination near Utah’s Zion National Park. A 16-acre property, AutoCamp Zion is located between the Virgin River and the desert of Southern Utah.
Headquarters | May 9, 2023
New Wells Fargo development in Texas will be bank’s first net-positive campus
A new Wells Fargo development in the Dallas metroplex will be the national bank’s first net-positive campus, expected to generate more energy than it uses. The 850,000-sf project on 22 acres will generate power from solar panels and provide electric vehicle charging stations.