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CEU ARTICLE

Advanced Threats Met with Advanced Technology


How breakthroughs in weather-resistant barriers can improve occupant well-being in all climates


By Kendra Palmer

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WRBs are vital to the construction of new residential and light commercial, multifamily, and mixed-use buildings to achieve occupant well-being, safety and comfort. New WRB technology can meet and exceed evolving standards for healthier buildings and homes. All photos courtesy of TYPAR.

Learning Objectives:

By the end of this course, the reader should be able to:

  1. Recognize the necessity for WRBs in modern construction for the safety and wellness of inhabitants.
  2. Explain the concept of wall cavities and how controlling air movement in wall cavities positively affects inhabitants’ comfort and well-being.
  3. Describe how properly draining exterior wall cavities improve the durability of a building.
  4. Differentiate WRBs according to environment, performance, and health criteria and remember other considerations before installation.
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Weather-resistant barriers (WRBs) are essential in the construction of new residential and light commercial, multifamily and mixed-use buildings. They help achieve occupant well-being, safety and comfort. With more people working and playing at home, as well as more commercial buildings constructed to higher standards, new WRB technology can meet and exceed standards for healthier buildings and homes. Technology can be designed to meet building requirements, a variety of climates, and the effects of climate change. Indoor air quality (IAQ) should increase comfort and even foster well-being for building occupants. Indeed, the EPA has shown that on average, people spend up to 90 percent of their time indoors. Indoor spaces need to be safe, durable, comfortable and efficient. People want to work and live in healthier buildings and homes.

The terminology and function of WRBs can be confusing, making it difficult to compare products. Sometimes WRB may refer to a water-resistive barrier, but there is a difference and they have distinct purposes. For the sake of this piece—and taking the definition from The American Architectural Manufacturers Association—a WRB is a weather-resistant barrier, a surface or wall responsible for preventing air and water infiltration into the structure’s interior.

WRBs used to be categorized as products that prevent water from entering buildings while under construction. Today, WRB products comprise a broader product group that prevents water, air, thermal, and vapor (or WATV) transmission from transferring from inside or outside of a home or building. WRBs, as part of a tight building envelope, can reduce heating and cooling costs up to 15 percent in some cases—while protecting buildings from harsh elements and improving comfort for occupants.1






Energy-efficient buildings with comfortable environments need air tightness and reduced thermal bridging to lower heating and cooling costs, and controlled moisture is necessary to keep building occupants comfortable and healthy. WRBs are critical in meeting improved IAQ and other needs in modern homes and buildings.

Modern WRBs are made of lightweight, synthetic material that are applied to homes and commercial buildings to protect them against air leaks, water, and moisture infiltration. They function as a shell for buildings—liquid that has penetrated the exterior finish can’t get through, but water vapor can escape. Though resistant to weather, they allow water vapor to pass from inside a building to its exterior, which prevents mold and rotting and increases a building’s energy efficiency and comfort. These materials are resistant to damage during installation, and they provide exceptional air- and water-blocking performance.

One of the differences between WRBs—sometimes referred to as “housewraps”—and building paper is the additional gap created by spacers, allowing moisture to drain from wall assemblies more quickly. Also the drainage channels form an unobstructed path behind cladding, avoiding the possibility of ponding along siding edges with traditional barriers.


Scientific History of WRBs

Already applied in successful reconstruction of dated European buildings, exterior insulation and finish systems (EIFS) were introduced in the United States in 1969. The evolution of wraps and barriers, starting in the early 1970s, saw innovations in different types of sheathing technology; these iterations are responsible for most of the water and air resistance in wall assemblies to date. The housewrap of that time—spurred by the energy crisis calling for more efficient products—provided a way to seal the exterior of a building and reduce air leakage. But other benefits of these barriers were apparent, including the ability to withstand high winds and offer flexibility at lower temperatures, and the ability to restrict air flow. In addition, the barriers were condensation-reducing and lightweight. The 1970s also brought asphalt-saturated felt paper, required by building codes to be installed as a WRB instead of paper-faced gypsum sheathing.

Concerns about energy conservation and product durability in the 1980s brought about gypsum board sheathing that replaced the paper facing with a fiberglass mat facing. This could be exposed to normal weather for longer periods of time compared to paper-faced sheathing. The fiberglass mat surface was a primitive but effective WRB surface. Fibrous building wraps were used on both residential and commercial construction mostly to create an air barrier, although some provided a WRB, too.

Other rigid board stock products came into the market in the ‘90s, and were meant to act as a sheathing or substrate behind cladding on an exterior wall. Most of these products needed to be covered quickly since they deteriorated rapidly in the elements. In the following decade, changes in the International Building Code (IBC) required WRBs to be applied to sheathing. Membranes were applied over the sheathing, but they were labor-intensive when it came to irregular areas. Of course, all the products and older versions of the modern technology are available and used to some extent today, which can complicate things, but this piece will focus on new construction.

About 10 years ago, the technology for fluid-applied membrane barriers continued to develop and they became more effective, allowing for thinner applications. Testing showed they were highly effective as a WRB and air barrier. The next innovation in this technology offers both a WRB and air barrier directly in the fiberglass-mat-faced gypsum sheathing, as well as an arsenal of other means to completely seal other openings. This reduces the dependence for effectiveness on the installer and utilizes the best products and their capabilities.

It is important that all professionals are current on these developments to ensure using the best-available solution for a project. The installer needs to be qualified and to demonstrate completed training and experience with WRB installation and then submit to testing and inspection once installation is done. A new building’s envelope should be built to control air leakage, avoid condensation in the interior wall assembly, and prevent water intrusion. Joints, penetrations, and paths of moisture and air infiltration should be made as watertight and airtight as possible but also be flexible, allowing for some movement of the system with variations in temperature and moisture.

Section 1: Why WRBs?
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It is important that professionals are qualified to install WRBs and then submit to testing and inspection once installation is done. A new building’s envelope should help control air leakage, avoid condensation in the interior wall assembly, and prevent water intrusion.

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WRBs offer further durability within high-performance energy systems in new buildings; they help increase total insulation R-values, help control moisture (and hence, mold), and increase energy efficiency, all helping to minimize maintenance costs.

"The minimum requirements in green standards alone may lack comprehensive measures to ensure long-term durability of the enclosure assemblies... "

Climates, Weather and WRBs

Different climates produce rain, heat, humidity, snow, and wind. High humidity and extreme temperatures often lead to moisture flowing from warm to cold (carried by air movement through leaks in the wall assembly) and condensing on the colder surface. Rain, driven by wind, can be forced into small openings in the exterior cladding such as joints, laps, utility cut-outs, electrical outlets and nail holes. Wind can create a negative pressure within the wall assembly, siphoning water into the wall. Some “reservoir” claddings such as brick, stone, and stucco can absorb and store moisture, which the sun then forces into the wall assembly, a process referred to as solar drive.

Geography and annual rainfall matter when it comes to WRBs. The Building Enclosure Moisture Management Institute recommends that any area that receives more than 20 inches of annual rainfall should use enhanced drainage techniques, while areas receiving 40 inches or more should utilize rainscreen design, regardless of cladding. The orientation of the wall in question, the overhang, altitude, and even nearby trees also can affect how much water can get in and how likely it is to dry.

Building scientists and other experts agree that no matter how tightly a building is constructed or how well it’s insulated, and no matter what type of cladding and how skillfully installed, moisture always will find a way into the building enclosure. This infiltration can undermine structural integrity, cause exterior surfaces to deteriorate, and shorten the life of paints and stains. Mold and rot can contribute to structural damage but also pose serious health risks. The main objective is ridding the wall assembly of moisture as quickly as possible when it gets in.


Changing Building Codes and the WRB Market Indicate Growth

As part of the complete building envelope, WRB products continue to evolve and the WRB market will continue to expand.

There are many moisture management products available, among them traditional felt paper, rainscreen systems, caulks, sealants and self-adhered flashing membranes. Choices are expanding, and they are spurred by advances in technology, desired green certification and other factors.

WRBs are no longer optional as they are required by all current building codes—and recommended by all building experts. For example, the 2018 IECC residential energy codes, adopted already by several states, require additional proven energy efficiency measures based on higher insulation values, tighter homes, and improved moisture management. Commercial building construction is moving to holistic design approaches favoring energy efficiency, internal environmental quality, and prolonged building durability. Zero-energy initiatives and others emphasizing innovation in integrated design for the entire building envelope continue to gain attention. All this drives the need for materials and systems that perform successfully over a wide range of conditions.

WRBs increase durability of new buildings in any climate. Effective air sealing, efficient HVAC systems, and fitting insulation are all part of best practices for new buildings, no matter the environment. Without a WRB, sheathing and other parts of the wall assembly would be much more susceptible to damage from the elements.





WRBs are part of a modern wall assembly, which may also entail window and door flashing and accessory materials for application to exterior building envelope substrates within a ventilated cavity. What are the benefits of starting with wall cavities?

With wall cavities, the wall system is divided into two separate parts with an airspace between them, creating a thermal break between the two distinct wall layers. They offer resistance to water penetration and air infiltration and can be filled with rigid insulation, which provides another thermal barrier. Cavity walls offer the potential for better thermal insulation than any solid wall because that space is full of air and reduces heat transmission. They are cheaper than other solid walls. The wall cavity is a good choice for many structures; it prevents more heat from escaping from the building and prevents as much cold air getting in. Cavity walls reduce their weights on the foundation.

The wall cavity can further perform as a drainage plane and a pressure equalizer for the siding.

What about controlling air movement in these walls? Benefits include improved air quality, good insulation values, moisture and temperature control and occupant comfort.


Improved Indoor Air Quality (IAQ)

This involves being able to move some indoor air pollutants outside and the air within the cavity no longer being stagnant. Using a device—such as ventilation systems, fans, spot ventilators, make-up air, and heating and air conditioning systems—helps ventilate a building and/or distribute conditioned air throughout a building. Ventilation also helps further remove or dilute indoor airborne pollutants coming from indoor sources and reduces the level of contaminants.


Good Insulation Values

Air is a proven, free, and a good thermal insulation material; the origin and the destination of the air depends on climatic conditions, building orientation and HVAC strategy. Cavity walls offer a heat flow rate that is 50 percent that of a solid wall. Insulation reduces heat transfer or flow, so it also can moderate the temperature across the building envelope cavity.


Moisture and Temperature Control

Air sealing and moisture control are essential for building energy efficiency. Moisture can cause problems in attics, some foundations and walls, and the solutions to those problems vary by climate.

Section 2: Wall Cavities and Benefits
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Air sealing and moisture control are essential for new buildings and their energy efficiency.



During the heating cycle in wall cavities, heat radiates from the sheathing to the foil, but is reflected back to the sheathing without warming up the foil from radiant heat transfer. During the air conditioning cycle, the exterior is heated, but with the foil, the heat is not transferred to the sheathing. So the cavity acts as a heat exchanger and exhausts the heat of the hot exterior, and the heat isn’t transmitted to the living or working space.


Occupant Comfort

The controlled movement of air within a building can directly contribute to occupants’ comfort through achieving improved IAQ and moisture and temperature control and providing good insulation values. In winter, movement of cooler air often is noticed as unwelcome drafts. In summer, though, air movement from either convection currents or by mechanical means over exposed skin enhances evaporation, making occupants feel both cooler and dryer.


WRB Qualities and Considerations for Wall Cavities

It is imperative that wall assemblies have the ability to dry out to prolong the durability of the wall. The permeability is the amount of vapor transmission a WRB allows over time while minimizing the potential for moisture vapor accumulation. The higher the permeance rating or perms, the more vapor-permeable the material. This number is somewhat nebulous because of variations in lab and installed conditions, but the perm rating should be higher than 5. Still, a higher perm rating doesn’t necessarily guarantee that it’s better—WRBs with micro-perforations may allow the passage of more water vapor, but they also can make it vulnerable to bulk water leakage. Other high-permeability WRBs may allow moisture stored in the reservoir cladding to be driven into the sheathing and insulation.

A WRB permeance in the range of 1 to 10 perms allows inward-driven moisture while still enabling outward drying in climate zones 1 to 7. Very low-permeance WRBs (less than 1 perm) should not be used unless there is 1 inch or more of exterior insulation (and at least 2 inches in climate zones 6 and 7).High-permeance WRBs (50 perms) should not be used with vapor permeable exterior insulation with reservoir claddings that are exposed to higher rain levels. Low-permeance interior vapor control results in elevated moisture content in the sheathing by capturing the inward-driven moisture; this should be avoided.

The biggest concern with vapor-permeable insulating sheathings is inward-driven moisture caused by solar drive hitting a wet moisture-storing cladding, which is a problem that occurs in all climates. When this happens, high vapor pressure builds behind the surface of the cladding, which can lead to outward drying but also create an inward vapor drive, particularly if the indoors is air-conditioned to a lower vapor pressure.

WRBs with an integrated rainscreen provide a continuous vented airspace over the entire surface area of the wall, providing better drainage and drying. Because many rainscreen products use a combination of plastic materials for the gap, they aren’t subject to saturation and decomposition that could compromise wood furring. These products are recommended in areas with wind-driven rain, high amounts of rainfall (40 to 60 inches annually), or those with high temperatures and humidity. New construction in coastal areas and those with hilltop exposures are key examples for locations where this technology should be applied.

There is an order for wall components in new construction. As far as placement in the wall assembly, the closer the wet materials are to the ventilated cavity, the higher their permeability should be.


Kendra Palmer has 12 years of experience working as an editor and writer for clients in renewable energy, healthcare and education. She is a frequent contributor for continuing education courses and publications through Confluence Communications. http://www.confluencec.com

Building Enclosure  |  BuildingEnclosureOnline.com  |  Fall 2021

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