The Physics of Thermal Inertia in Low-Slope Roof Design

Low slope roof penetrations can be a source of problems if not done correctly. Pipe, vent, and conduit penetrations through low slope roof assemblies can cause problems for an otherwise tight membrane, insulation, and deck design. With many intermediate layers in roof assemblies, such as a vapor retarder and cover board, there are opportunities for things not to be done correctly somewhere in the assembly. It gets even more complex when we consider that in order to use a vapor retarder, there might be an additional cementitious board above a steel deck. This article provides an overview and is intended to be used as general guidance only. For specifics refer to the GAF Single-Ply Pro Field Guide and, when using the GAF SA Vapor Retarder also review the Guide to Vapor Retarder Design in Low-slope Roof Systems. Let's look at each part of the roof assembly, starting at the bottom: Deck Level: If a separate vapor retarder is being installed, this is where it will be placed; either direct to deck or onto a cementitious board or HD polyiso. A self-adhered vapor retarder installed at the deck significantly reduces the diffusion of moisture and blocks the movement of interior humid air up into the roof assembly. Any penetration needs to be flashed carefully to prevent interior air from bypassing the vapor retarder. Best practice is to field fabricate a collar out of the vapor retarder and wrap it around the pipe as shown here: A target sheet is then placed over the collar and any remaining gaps can be sealed with GAF Flexseal™ Caulk Grade Sealant. The completed flashing is shown below: Important – as shown in the schematic above, sometimes the gap around a deck penetration is larger than can properly support a flashing. When this is the case, be sure to fill the gap with foam, using a foam pack, to act as a support and to block air flow. This also helps further reduce the risk of air infiltration from the building interior up into the roof assembly. Insulation / Coverboards It is not unusual to see gaps around penetrations through insulation and coverboards. These gaps don't just act as thermal bridges but they also allow air to freely move up into the roof assembly. This is especially true for mechanically attached membranes during wind events. Best practice is to fill the gaps with foam as shown here: By filling any gaps between penetrations and insulation and coverboards, the risk of interior humid air reaching the underside of the membrane is minimized. This in turn reduces the risk of condensation issues in cold climates. Important - Always make sure that the two layers of insulation have staggered and offset joints. If coverboard is used, also ensure that its joints are staggered and offset from those of the topmost layer of insulation. In this way, air movement up through the assembly can be minimized. Single-Ply Roof Membrane Penetrations through single-ply roof membranes can be sealed with field fabricated flashings or prefabricated accessories. While field fabrication can be successful, the risks of inconsistency and errors can be reduced by using one of a range of prefabricated accessories designed to help flash in penetrations. The GAF TPO Accessories are a good place to start, allowing many situations to be addressed such as inside and outside corners, penetrations, vents, and skylights. These are discussed in more detail here. Keeping with the example of a pipe penetration, the following shows how to properly install a pre-molded pipe boot: Note that for a mechanically attached membrane, an additional four fasteners should be used around the penetration. A target patch can be required if the four fasteners need to be spaced further away from the penetration to ensure a good anchorage. However, the GAF vent boot is designed with a large 6 inch flange that often eliminates the need for a target patch. Important – as has been stressed before, do a final check that gaps around the penetration are sealed with foam, before doing this final installation. In many cases, condensation issues first occur around a penetration due to the ability of interior air to bypass the insulation layers and reach the underside of the roof membrane. Note that GAF offers custom cylindrical pipe boots which can be custom fit to the penetration to eliminate any air on the inside of the accessory which can help reduce condensation. Important Considerations The purpose of this article is to provide some background information and design considerations for addressing roof penetrations. GAF manufactures and sells roof materials but is not responsible for building design and construction. Design responsibility remains with the architect, engineer, roofing contractor, or owner. This information should not be construed as being all-inclusive, nor should it be considered as a substitute for good application practices. Please consult your design professional for more information.

Vapor retarders are increasingly being specified for inclusion in low slope roof assemblies. They can help manage humid air migration from the building interior up to the underside of the roof membrane. Also, they can help limit the amount of moisture migrating from a concrete deck up into the roof assembly. In fact, we offer the GAF SA Vapor Retarder, a self-adhering sheet product, to help reduce this risk. If you are designing a new roof and want to reduce possible moisture risks or are replacing a roof assembly where there's evidence of moisture issues, this article may help you to understand more about the use of vapor retarders. In addition to this article, we also have a Guide to Vapor Retarder Design in Low-slope Roof Systems which describes best installation practices. The guide and this article are intended to address the basics of vapor retarders for designers who want to address moisture migration. Later articles will cover more fundamental considerations. The answers to these frequently asked questions may sometimes repeat key information, and the reader can jump to those questions of most interest. But reading all of the answers will help get a better overall understanding of the function and role of vapor retarders. What is a vapor retarder? It is a material that, depending on its exact specification and correct installation, blocks or slows down the transmission of moisture from one side to the other. Vapor retarders can be coatings, boards with taped joints, or membranes. Looking at this schematic, it is clear that in an actual roof assembly any penetrations have to be sealed otherwise the vapor retarder's function is degraded – more on this later. How does a vapor retarder function? A properly installed vapor retarder at the deck level can help slow down or block the movement of moisture from the building's interior migrating up into the roof roof assembly. Blocking or slowing down the movement of moisture can be part of an effort to lower condensation risks within the roof system during cold winter months. Vapor retarders can also have some degree of moisture permeability. There are different classes of vapor retarding material (I, II, and III) and each class of material allows differing amounts of moisture vapor to pass through the materials via diffusion. The ability to limit vapor movement, but allow some moisture vapor to pass through the material, can be important because it can prevent having trapped moisture within the roof system. Roof membranes are moisture impermeable, so if moisture does get into the assembly, a properly specified vapor retarder with some degree of moisture permeability can allow the moisture to slowly escape downwards. How does a vapor retarder differ from an air barrier? To state the obvious, properly installed air barriers block air, and as a result will also block the movement of humid air, thereby retarding or stopping most moisture movement. So, they can appear to be very similar and sometimes identical. But, the use or application of each is normally different. For more on this, check out this article. A good roof membrane, such as GAF EverGuard TPO will not only block air and moisture but also withstand ordinary wear and tear. A good vapor retarder, such as GAF SA Vapor Retarder, is normally used within a roof assembly to reduce moisture movement. It will have limited or even zero permeability as its primary purpose is to reduce the movement of moisture. While it can act as a temporary roof, it is not intended to be wear- and tear-resistant in the same way as a roof membrane. Is a vapor retarder required? Building codes do not require the installation of a vapor retarder in roof assemblies. A determination as to whether to include a vapor retarder must be made by a design professional. Other answers in this article may help frame what could be considered for such a decision, but a design professional must make the ultimate determination based on the specific conditions at a given project. Basically, a vapor retarder can be specified and correctly detailed in order to manage the migration of moisture vapor to prevent wetting and enable drying within a roof assembly. Does vapor retarder use depend on a building's location? The location has a significant impact on the decision to incorporate a vapor retarder into a roof assembly. The building designer should consider the main direction of moisture drive within the building enclosure. Keep in mind that moisture drive is normally from warm (high vapor pressure) to cold (low vapor pressure). If the building is located in the north, moisture drive is the strongest in the winter. The building interior is usually at a warmer temperature than the exterior. Any interior humid air that reaches the external enclosure layers could cause condensation due to the lower external temperatures. In a roof assembly, a vapor retarder located towards the bottom side of the roof assembly can help reduce or throttle back the migration of water vapor from the interior warm side to the exterior cold top of the roof assembly. For a normal building occupancy and where the building is located in a consistently humid climate, the moisture drive is predominantly towards the interior of the building. In this case, exterior hot humid air that is able to penetrate through the building enclosure can form condensation on interior colder surfaces. Roof membranes are inherently vapor retarders so downward or inward vapor drive is blocked. For buildings with high occupant moisture generation, or that are located somewhere with a mixed vapor drive depending on the season, the roof designer should consider the appropriate roof assembly for the application. If moisture drive from the interior up into the roof assembly could lead to condensation within the roof assembly, then a vapor retarder should be considered. Isn't the roof membrane a vapor retarder? Why do I need another one? Roof membranes are generally vapor impermeable, but to be considered as vapor retarders one has to consider their use. In northern buildings where vapor drive is upwards through the roof assembly, the roof membrane is acting as a barrier to the external weather. It can also be used as an air barrier, preventing interior conditioned air from escaping, but it doesn't prevent interior humid air from moving upwards through the roof assembly. If water vapor is able to migrate upwards towards the roof membrane, then there can be a condensation risk depending on factors such as the exterior temperature and the interior humidity level. Where should a vapor retarder be placed within a roof assembly? The simplest answer to this question is as close to the interior conditioned space as is practically possible. However, always check that local fire codes allow for self-adhering membranes applied directly to steel decks. In many cases it is necessary to first install a gypsum or cementitious board over a steel deck which is then used as a substrate for the adhered vapor retarder. Always check with the roof system designer to make sure that a proposed system meets all necessary codes. Alternatively, the vapor retarder could be applied to the topside of the first layer of insulation, but in such a case, the designer would need to confirm that the dew point would be above the vapor retarder. Can I use black poly (e.g. Visqueen) as a vapor retarder? Black poly sheet, technically 6 mil polyethylene, is often used as a vapor retarder in residential crawl spaces. However, its use in roof systems is generally not recommended for several reasons: It does not self-seal around fasteners that penetrate through it. Vapor retarders such as GAF SA Vapor Retarder are designed to meet a self-seal test described in ASTM D1970. Polyethylene is notoriously difficult to adhere to, which makes flashing and sealing around penetrations very difficult and unlikely to be durable. 6 mil polyethylene is essentially impermeable, which means that any leak in the roof covering will let in water that can't escape. Also, if some water has been present when the roof was closed up, from dew or light rain during the previous night, it will not be able to escape. Properly specified vapor retarders have some degree of permeability that will allow for migration of water from within a roof assembly downwards. The only exception to this may be for a building with a very high interior humidity when it might be advisable to have a vapor retarder with essentially no permeability My building is in the north, so do I automatically need a vapor retarder? No, a roof designer needs to evaluate the risk of condensation occurring. The building use, the type of building, and the roof assembly design are important considerations. An evaluation of condensation risk asks questions including: What is the humidity level likely to be in the building? Office buildings can be expected to have lower levels versus buildings with restaurants or indoor pools. If activities within the building could generate high humidity levels, has the HVAC system been designed to reduce the levels with make-up air? What is the building's location and what are the coldest exterior temperatures that could be expected? Will the roof assembly inhibit air flow without the use of a vapor retarder? Some roof assemblies, particularly those that have adhered layers, are more restrictive of air flow than others. Once interior humidity levels have been estimated and outdoor cold temperatures known, then the building designer can calculate where the dew point will be in the roof assembly. If the designer specifies a vapor retarder, it should always be located below the dew point. How should a vapor retarder be tied in, flashed to penetrations, etc? To be successful, penetrations through the vapor retarder need to be flashed and air tight. Also, the edges need to be terminated to the walls. Care has to be taken to ensure that interior air cannot readily move past the vapor retarder and up into the roof assembly or a parapet wall. The GAF Guide to Vapor Retarder Design in Low-slope Roof Systems provides system details to help guide good design. Should a vapor retarder be used with a concrete deck? In new construction, it can be difficult to ascertain when concrete decks are sufficiently dry to allow the roof assembly to be installed. If significant levels of moisture are present in the concrete deck after the roof is closed up, then problems can arise. For more on the topic of moisture in concrete roof decks see this article by my colleague James Kirby. Briefly, as advised by industry groups such as the Midwest Roofing Contractors Association (MRCA), the use of a vapor retarder over a concrete deck will limit moisture passing through to the roof assembly. In re-roofing situations over concrete decks, there is usually less concern about moisture being present within the concrete deck, providing that there have been no leaks. However, if the roof was originally installed with minimal insulation, it could be that the concrete contains significant amounts of moisture due to condensation, depending on the local climate. Also, any precipitation during reroofing could allow a concrete deck to absorb quantities of water. If there is any concern about moisture in an existing concrete deck, a vapor retarder should be considered. In new construction, is there a concern about moisture from a concrete floor or foundation? Yes, there can be, depending on location and other factors. In some big box construction, when the building has been closed up quickly after a floor slab was poured, condensation issues have occurred during the first year of occupancy. This is related to high interior humidity as the concrete dries out for months during and after construction. Concrete floors and foundations can take a long time to dry and as a result interior moisture levels can be high enough that condensation has been known to occur in climate zones 3 and 4. Building designers and architects of such buildings often include a vapor retarder in the roof assembly in order to reduce condensation risks during construction, after the building is closed up, and for up to 12 months later. What about where the vapor retarder meets the edge of the roof? Sealing and termination of vapor retarders around the perimeter is difficult. Building designers should recognize that the goal of a vapor retarder is to block the movement of interior humid air up into a roof assembly and to controllably allow for some vapor permeability so that moisture that does enter the roof assembly can migrate down into the building. The GAF Guide to Vapor Retarder Design in Low-slope Roof Systems provides edge termination details to help guide good design. I often see dew point and vapor retarders being discussed together. Why? It's important to make sure that a vapor retarder is installed below where the dew point in the roof assembly is calculated to be. The vapor retarder will then reduce the likelihood of moisture reaching that position and forming condensation during cold periods. Calculation of the dew point takes into account the expected interior humidity levels and the possible exterior temperatures. More information about the calculation can be found here. What is condensation risk and should I always include a vapor retarder? Moisture is well known to lead to problems with respect to the durability of a building enclosure. The risk of condensation within a roof assembly should be assessed by a design professional. The analysis should consider factors including climate and building use. It is important to recognize that there often is not a definitive yes/no answer to the question as to whether a vapor retarder is needed. The colder the climate, the higher the risk of condensation within the roof assembly. So, buildings located in northerly regions will generally have a higher risk of condensation forming in the building enclosure. The higher the anticipated interior moisture load, the higher the risk. Office buildings occupied during daytime only are likely to have a lower risk versus a building that includes a swimming pool. A building closed up during construction while a concrete slab floor is still drying will likely have a higher risk. The roof assembly design is also a factor. High wind events can cause mechanically attached single-ply membranes to billow which causes air to be drawn up into the assembly, which can increase the risk of condensation. To minimize condensation risk, roof designers should first consider adhering the roof membrane and upper layer of insulation, making it harder for interior air and moisture to be drawn up into the assembly. If a cover board is being used, it should also be adhered. Conclusions Vapor retarders can be used to reduce the movement of vapor within a roof assembly. They need to be positioned as low as practical within the assembly and any penetrations should be sealed. Vapor retarders in the roof assembly may be beneficial in buildings with large temperature differences from interior to exterior throughout the year, and occupancies with higher than normal interior moisture levels, either from use or during construction. Important Considerations The purpose of this article is to provide some background information and design considerations for roofing assemblies using vapor retarders. GAF manufactures and sells roof materials but is not responsible for building design and construction. Design responsibility remains with the architect, engineer, roofing contractor, or owner. This information should not be construed as being all-inclusive, nor should it be considered as a substitute for good application practices. Please consult your design professional for more information.

Thermal insulation is an important part of commercial roofing assemblies. As with anything, there are ways to design with and install polyiso insulation — a better way, a best way, and many variations in-between! What may be best in terms of lowest up-front costs, may prove only good or worse over the long-term life of the building.As discussed later, important points to remember about polyiso and its use include:Due to polyiso's very low air permeability, good design and installation practices can result in low risks of condensation, even for buildings with somewhat higher than normal humidity levels.Building designers can use the label R-value, stated at a mean temperature of 75°F, for projects in most ASHRAE climate zones. However, for climate zones 6 and 7, it may be appropriate to use published values at 40°F.Electricity is four times as expensive as gas, on an equivalent Btu basis. Therefore, polyiso's greatest value is seen during summer months when air conditioning usage is at its highest.IntroductionPolyiso has become the go-to insulation for commercial roofing with about 75% market share. The reasons include:Lowest cost per R-value.High R-value per inch, meaning it doesn't require as much thickness as other types of rigid insulation to achieve the same insulation performance.Good fire resistance. Being a thermoset unlike polystyrene foams, it doesn't melt during a fire. Melting of thermoplastic foams and subsequent flowing down of molten material through the deck into a building can be hazardous for occupants and fire crews.Solvent compatibility — adhesives used in adhered systems don't adversely affect polyiso. This is not the case with polystyrene foams.Reduced condensation — When installed correctly in a properly designed system, polyiso helps to resist interior air from reaching the underside of the membrane, thereby reducing condensation risks.However, just because polyiso is specified and used doesn't mean that the ideal outcome is reached. There are installation details that need to be considered.Single-ply membrane combined with polyiso can make for a good roof, but additional factors can improve performance:The BasicsPolyiso boards have straight cut edges (the boards are not tongue and grooved). These butt joints between boards can allow for vertical air movement.Polyiso was often installed as a single layer:As shown in the figure above, a single layer of butt-jointed insulation is generally a bad idea and is no longer allowed by the International Building Code (IBC) in the 2018 and newer versions. For roofs with a single layer of butt-jointed insulation boards:There is little restriction for air flow and so, during wind events, wind uplift forces result in membrane billowing for attached systems.Membrane billowing draws interior conditioned air up to the underside of the membrane and may create a risk of condensation within the assembly.Billowing may place additional stress on membrane fasteners, a factor recognized by membrane manufacturers by the issuance of shorter guarantees or warranties for mechanically attached versus adhered membrane.Essentially unrestricted air flow up into the assembly diminishes the insulation value and lowers energy efficiency.In contrast, two layers of polyiso restrict the free flow of air into the roof assembly. Care must be taken to seal between roof penetrations and the polyiso, or air is still free to move up into the assembly as shown here:Spray foam is a good choice for achieving a seal between the polyiso and the penetrations.Two layers of polyiso with staggered joints and sealed penetrations is a good system, but two of its features still reduce its insulation efficacy. These are shown in the following magnified view of a roof assembly cross-section.This cross-section illustrates lower energy efficiency resulting from:Insulation and membrane fasteners both act as thermal bridges, conducting heat through the assembly.Gaps between insulation boards that allow thermal convection to occurWhen both the insulation and membrane are attached and fastener densities are at their highest, R-value reductions of up to 29% have been predicted.Adhered versus AttachedThe alternative to mechanical attachment is to adhere the insulation with adhesive. Typically, low rise foam is the adhesive used for both insulation and cover board installation. The original method of application was as a ribbon but for labor savings it is often sprayed in a spatter-pattern as shown in the following picture of a typical installation in progress using one of GAF's low rise foamsUsually, when polyiso is adhered, the roof membrane is also adhered. For a steel deck substrate, fasteners are typically only used for the first layer of insulation, and then the adhesive is used on the subsequent layers of insulation and membrane. While it may be possible to adhere directly to a steel deck and eliminate fasteners totally, this approach is more common with concrete decks, as shown in the schematic here:Key features of systems with adhered insulation are:Air flow up through the assembly is limited and the risk of condensation in cold climates is low. Similarly, membrane billowing is minimized due to the restricted air flow up through adhered insulation layers.Thermal bridging is minimized since only the first layer of insulation might be mechanically attached. With concrete decks, the first layer of polyiso can be adhered thereby eliminating the use of fasteners totally.Wind uplift resistance is uniformly distributed across the roof deck. A system with adhered membrane and insulation can act as a monolithic system with excellent wind uplift resistance.When combined with an adhered membrane the finished roof appearance is usually aesthetically pleasing. When applied in accordance with manufacturer's instructions, the membrane can be very flat and there will not be any insulation fasteners to telegraph through and mar the appearance.Induction WeldedInduction welded fasteners are another type of roof attachment, the largest type being the Drill-Tec™ RhinoBond® system. By definition this is a mechanical attachment method but it has many of the features of adhered systems. The technique fastens TPO and PVC membranes to the substrate below using a microprocessor controlled induction welding machine. The thermoplastic roof membrane is welded directly to specially coated fastening plates used to attach the insulation. The picture below shows such a system being used:The induction machine is placed above each plate in turn and activated for approximately 10 seconds. As the machine is moved to the next position, a weighted magnet is placed over the plate and acts to squeeze the membrane down onto the hot fastener plate causing it to weld to that plate's surface coating.For typical mechanical attachment of single-ply membranes with fasteners along the seam lines, the insulation boards are simply secured with five fasteners per 4 x 8 ft. board to keep them flat. When using a Drill-Tec™ RhinoBond® system, the combined insulation and membrane fasteners resist wind uplift forces as shown in this picture during a test of wind uplift resistance:This means that wind loads are more uniformly distributed versus a conventionally attached system.Key features of systems with induction welded membrane attachment are:Performance is very similar to adhered in terms of the distribution of loads.Thermal bridging is reduced compared to traditional mechanically attached membrane systems.There are no application temperature restrictions and so this approach can be used in place of adhesive attachment regardless of how cold it might be.Drill-Tec™ RhinoBond® systems can be cost competitive due to the speed of installation as compared with traditional bucket and roller adhesives.Dew Point CalculationsThe dew point is the temperature at which moisture vapor forms condensation. It's a function of the relative humidity and the ambient temperature. The evaluation of a roof assembly where the dew point might be reached is an important step towards designing a roof with minimized condensation risks. The topic has been covered in greater depth elsewhere, but this section summarizes the key steps. Examine the chart below (this is a simplified form of what is used by HVAC engineers).Locating 40% relative humidity in the first column and then going across to the 70°F, design dry bulb temperature shows a dew point of 45°F. This means that in an environment that is 70°F and 40% relative humidity (RH), water in the air will condense at a temperature of 45°F. A roof assembly separates the interior conditioned environment from the outside and the insulation layer in the roofing system resists heat loss or gain to/from the outside, depending on the season. Within the insulation layer the temperature has a gradient between the hot and cold side, i.e. between inside and outside.As an example, consider a building in the winter to illustrate the point. The interior is 70 °F with 40% RH, like the example on the chart above. The temperature gradually drops from the innermost part of the insulation until at the outermost part it will be at the exterior, cold temperature. The plotting of temperature through the insulation thickness is referred to as the temperature gradient of that system. Using the example, if the temperature gets to the dew point of 45°F at any point in that system then water would be expected to condense on the nearest surface. This is shown in the following diagram:Summarizing, in this example the interior air has 40% of the total water vapor that it can support. But as the air migrates up through the roof system, it gets cooler until the point where it can no longer hold onto the water vapor and condensation occurs. In the example shown above, that's at 45°F and just inside the insulation layer.As will be discussed later, dew point calculations can be used to inform the placement of a vapor retarder layer when used.When a dedicated vapor retarder layer is not used, it is good practice to ensure that the dew point is in the upper layer of polyiso insulation. This will lower the risk of interior air migrating up through the roof assembly and condensing on a surface below its dew point.Using Vapor Retarders with PolyisoVapor retarders can be used to limit humidity ingress to the roof assembly. Under certain circumstances, depending on the building use and location, condensation can occur as discussed in the previous dew point discussion. In general there are four basic building conditions that can be considered:1. Buildings with Standard Amounts of Occupancy-Generated MoistureThese are the most common situations covering for example, office, retail, and warehouse spaces. The risk of having a condensation issue is low and good roofing practices such as sealing around penetrations may likely suffice.2. Buildings with Larger Amounts of Occupancy-Generated MoistureThis category includes apartments and other multiple residency buildings, paper mills, laundries, buildings with indoor swimming pools, and the like. In fact, anything that doesn't fit into category 1 above should be evaluated to determine humidity levels. The building's air handling and ventilation systems should be carefully specified to take into account the moisture loading.3. Construction–Related MoistureMost construction practices release some amount of moisture into the building space. These can be relatively short term such as drywall installation and painting. However, some practices can release large amounts of water over a considerable time frame into the building. These include poured in place concrete floors and roof decks.4. Concrete Roof DecksThese can present a challenge for roof system designers especially in new construction. Regardless of the type of concrete, significant amounts of water remain after curing is completed. Allowing concrete to thoroughly dry is most appropriate; however, it is often reasonably impractical. Dealing with potential moisture in concrete decks is beyond the scope of this article, but guidance can be found elsewhere.It is recommended that a building science professional experienced in designs for Categories 2, 3, and 4 be involved to determine whether a vapor retarder should be used and what type.Specification of R-ValuePolyiso is manufactured to meet the ASTM C1289 Standard Specification for Faced Rigid Cellular Polyisocyanurate Thermal Insulation Board. ASTM C1289 specifies the thermal resistance at a mean temperature of 75°F for various product thicknesses and requires that the values at 40 and 110°F be made available upon request.Important features of manufacturer's published R-values are:The values are an average across a temperature range. The test methods need the insulation specimen to have a hot and a cold side at least 40°F apart. Most reputable test labs use a difference of 50°F for accuracy. A published value at 75°F is actually an average R-value across the range of 50 to 100°F.To take into account the diffusion of gas out of, and air into the polyiso foam, the values are based on projected "Long Term Thermal Resistance" or LTTR, obtained by rapidly aging thin slices of the foam.The Polyisocyanurate Insulation Manufacturers Association, PIMA, conducts a third-party certification program to independently validate LTTR values. This is referred to as the PIMA QualityMark™ program. The LTTR values are considered as "labelled R-values" to be used by building design professionals.Label R-values represent a 15-year time-weighted average value. They can help a design professional estimate a building's energy efficiency without having to be concerned about long-term loss of performance, which is already factored into the value.Building design professionals designing roofs for ASHRAE climate zones 6 and 7 may need to use the R-value reported for a mean temperature of 40°F.Attachment PatternsThe various fastener patterns for polyiso have been mentioned in the previous sections. However, due to the impact of fasteners on thermal bridging and wind uplift resistance, the key points are summarized here:For systems that have both mechanically attached membrane and insulation, the membrane attachment provides the wind uplift resistance. The polyiso insulation fasteners are simply there to hold the insulation flat during the roof installation and to resist long term lateral movement.Typical fastener patterns are shown here:For systems with adhered single-ply membrane and mechanically attached polyiso boards, the insulation fasteners provide the wind uplift load resistance. This is the case whether both layers of polyiso are mechanically attached or only the bottom layer (in which case the upper layer would be adhered).Manufacturers have tested the fasteners per board required to meet wind uplift resistance requirements for these combined mechanically attached and adhered systems. The number of fasteners needed depends on the board size and thickness. For common systems, the numbers are shown in the table below:For each of these combinations above, manufacturers' handbooks provide fastener patterns.The number of fasteners for these combined mechanically attached and adhered systems is very large, for example a 125,000 s.f. big box type roof could require around 50,000 fasteners, resulting in significant thermal bridging.When installing over a steel deck, to reduce thermal bridging and to make for a more robust system with reduced condensation risk, it is advisable to only attach the first layer of polyiso and to adhere all subsequent layers and the membrane.If the first layer of polyiso is attached and the rest of the system adhered, then using a 1.5" thickness for that first layer would help to bury the thermal bridging fasteners. It could also put the dividing line between first and second polyiso layers below the dew point, which is advisable.ConclusionsPolyiso is a cost-effective roof insulation and has the advantage that its permeability is low. Good design and installation practices can result in low risks of condensation even for buildings with higher than normal humidity levels.When designed correctly, mechanically attached components with two layers of polyiso having staggered and offset joints can be part of a successful roof system.Adhered insulation and membrane roof systems have advantages including reduced or eliminated thermal bridging, lowered condensation risks, and better wind uplift resistance.In cases where building use anticipates higher interior humidity levels and/or the local climate suggests higher condensation risk, then a building science professional should be consulted as to vapor retarder use and specification.Building designers and specifiers are advised to use the labelled R-values shown for a mean temperature of 75°F. For projects in ASHRAE climate zones 5 and 6, values at 40°F could be used depending on the building's geometry and local energy costs.