RoofViews

Science du bâtiment

Est-ce que les assemblages de toitures hybrides valent-ils vraiment la peine?

By Kristin Westover

28 décembre 2023

An aerial shot of the student housing building on the Texas A&M campus.

Comment est-ce que les assemblages de toitures contribuent à l’efficacité énergétique, la robustesse, et les objectifs de durabilité d’un bâtiment? La selection intentionnelle des matériaux augmentera la robustesse de l’assemblage y compris la capacité de survivre à une tempête, une isolation adéquate aidera à maintenir les températures intérieures et faire des économies énergétique, et les matériaux plus durables peuvent tenir plus longtemps ayant pour résultat des remplacements moins fréquents. Les assemblages de toitures hybrides sont la dernière tendance en matière de toitures visant à atteindre ces objectifs, mais est-ce qu’elles sont à la hauteur du matraquage?

What is a hybrid roof assembly?

A hybrid roof assembly is where two roofing membranes, composed of different technologies, are used in one roof system. One such assembly is where the base layers consist of asphaltic modified bitumen, and the cap layer is a reflective single-ply membrane such as a fleece-back TPO or PVC. Each roof membrane is chosen for their strengths, and together, the system combines the best of both membranes. A hybrid system such as this has increased robustness, with effectively two plies or more of membrane.

Asphaltic membranes, used as the first layer, provide redundancy and protection against punctures as it adds overall thickness to the system. Asphaltic systems, while having decades of successful roof installations, without a granular surface may be vulnerable to UV exposure, have minimal resistance to ponding water or certain chemical contaminants, and are generally darker in color options as compared to single ply surfacing colors choices. The addition of a single-ply white reflective membrane will offset these properties, including decreasing the roof surface temperatures and potentially reducing the building's heat island effect as they are commonly white or light in color. PVC and KEE membranes may also provide protection where exposure to chemicals is a concern and generally hold up well in ponding water conditions. The combination of an asphaltic base below a single-ply system increases overall system thickness and provides protection against punctures, which are primary concerns with single-ply applications.

Pictured Above: EverGuard® TPO 60‑mil Fleece‑Back Membrane

OlyBond 500™ Adhesive

RUBEROID® Mop Smooth Membrane

Millennium Hurricane Force ® 1-Part Membrane Adhesive

DensDeck® Roof Board

Millennium Hurricane Force ® 1-Part Membrane Adhesive

Isolation en polyiso EnergyGuardMC

Millennium Hurricane Force ® 1-Part Membrane Adhesive

Platelage en béton

Pictured Above: EverGuard® TPO 60‑mil Fleece‑Back Membrane

GAF LRF Adhesive XF (Splatter)

RUBEROID® HW Smooth Membrane

Fixations et plaques Drill-TecMC

DensDeck® Prime Gypsum Board

Isolation en polyiso EnergyGuardMC

Isolation en polyiso EnergyGuardMC

Retardateur de diffusion de vapeur SA XL de GAF

Platelage en métal

Where are hybrid roof assemblies typically utilized?

Hybrid roof assemblies are a common choice for K-12 & higher education buildings, data centers, and hospitals due to their strong protection against leaks and multi-ply system redundancy. The redundancy of the two membrane layers provides a secondary protection against leaks if the single-ply membrane is breached. Additionally, the reflective single-ply membrane can result in lower rooftop temperatures. The addition of a reflective membrane over a dark-colored asphaltic membrane will greatly increase the Solar Reflectance Index (SRI) of the roof surface. SRI is an indicator of the ability of a surface to return solar energy into the atmosphere. In general, roof material surfaces with a higher SRI will be cooler than a surface with a lower SRI under the same solar energy exposure. A lower roof surface temperature can result in less heat being absorbed into the building interior during the summer months.

Is a hybrid only for new construction?

The advantage of a hybrid roof assembly is significant in recover scenarios where there is an existing-modified bitumen or built-up roof that is in overall fair condition and with little underlying moisture present. A single ply membrane can be installed on top of the existing roof system without an expensive and disruptive tear-off of the existing assembly. The addition of the single-ply membrane adds reflectivity to the existing darker colored membrane and increases the service life of the roof assembly due to the additional layer of UV protection. Additionally, the single-ply membrane can be installed with low VOC options that can have minimum odor and noise disturbance if construction is taking place while the building is occupied.

Is the hybrid assembly hype worth it?

Absolutely! The possibility to combine the best aspects of multiple roofing technologies makes a hybrid roof assembly worth the hype. It provides the best aspects of a single-ply membrane including a reflective surface for improved energy efficiency, and increased protection against chemical exposure and ponding water, while the asphaltic base increases overall system waterproofing redundancy, durability and protection. The ability to be used in both new construction and recover scenarios makes a multi-ply hybrid roof an assembly choice that is here to stay.

Interested in learning more about designing school rooftops? Check out available design resources school roof design resources here. And as always, feel free to reach out to the Building & Roofing Science team with questions.


This article was written by Kristin M. Westover, P.E., LEED AP O+M, Technical Manager, Specialty Installations, in partnership with Benjamin Runyan, Sr. Product Manager - Asphalt Systems.

About the Author

Kristin Westover, P.E., LEED AP O+M, is a Technical Manager of Specialty Installations for low-slope commercial roofing systems at GAF. She specializes in cold storage roofing assemblies where she provides insight, education, and best practices as it relates to cold storage roofing. Kristin is part of the Building and Roofing Science Team where she works with designers on all types of low-slope roofing projects to review project design considerations so designers can make informed roof assembly decisions.

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Avez-vous déjà pensé à des produits de construction qui réduisent les émissions de dioxyde causées par votre bâtiment? When considered over their useful life, materials like insulation decrease total carbon emissions thanks to their performance benefits. Read on for an explanation of how this can work in your designs.What is Total Carbon?Total carbon captures the idea that the carbon impacts of buildings should be considered holistically across the building's entire life span and sometimes beyond. (In this context, "carbon" is shorthand for carbon dioxide (CO2) emissions.) Put simply, total carbon is calculated by adding a building's embodied carbon to its operational carbon.Total Carbon = Embodied Carbon + Operational CarbonWhat is Embodied Carbon?Embodied carbon is comprised of CO2 emissions from everything other than the operations phase of the building. 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By Authors Elizabeth Grant

Le 18 septembre 2024

Flat roof with hot air welded pvc membrane waterproofing for ballasted system
Science du bâtiment

Ponts thermiques sur les fixations de toit : Pourquoi l’industrie devrait en tenir compte

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By making our buildings more robust against wind uplift to meet updated standards, we are in effect making them less robust against the negative effects of hot and cold weather conditions.So, how bad is this problem, and what's a roof designer to do about it? A team of researchers at SGH, Virginia Tech, and GAF set out to determine the answer, first by simplifying the problem. Our plan was to develop computer simulations to accurately anticipate the thermal bridging effects of fasteners based on their characteristics and the characteristics of the roof assemblies in which they are used. In other words, we broke the problem down into parts, so we could know how each part affects the problem as a whole. We also wanted to carefully check the assumptions underlying our computer simulation and ensure that our results matched up with what we were finding in the lab. The full paper describing our work was delivered at the 2023 IIBEC Convention and Trade Show, but here are the high points, starting with how we set up the study.First, we began with a simple 4" polyisocyanurate board (ISO), and called it Case A-I.Next, we added a high-density polyisocyanurate cover board (HD ISO), and called that Case A-II.Third, we added galvanized steel deck to the 4" polyiso, and called that Case A-III.Finally, we created the whole sandwich: HD ISO and ISO over steel deck, which was Case A-IV.Note that we did not include a roof membrane, substrate board, air barrier, or vapor retarder in these assemblies, partly to keep it simple, and partly because these components don't typically add much insulation value to a roof assembly.The cases can be considered base cases, as they do not yet contain a fastener. We needed to simulate and physically test these, so we could understand the effect that fasteners have when added to them.We also ran a set of samples, B-I through B-IV, that corresponded with cases A-I through A-IV above, but had one #12 fastener, 6" long, in the center of the 2' x 2' assembly, with a 3" diameter insulation plate. These are depicted below. The fastener penetrated the ISO and steel deck, but not the HD ISO.One visualization of the computer simulation is shown here, for Case B-IV. The stripes of color, or isotherms, show the vulnerability of the assembly at the location of the fastener.What did we find? The results might surprise you.First, it's no surprise that the fastener reduced the R-value of the 2' x 2' sample of ISO alone by 4,2 % in the physical sample, and 3,4 % in the computer simulation (Case B-I compared to Case A-I).When the HD ISO was added (Cases II), R-value fell by 2,2 % and 2,7 % for the physical experiment and computer simulation, respectively, when the fastener was added. In other words, adding the fastener still caused a drop in R-value, but that drop was considerably less than when no cover board was used. This proved what we suspected, that the HD ISO had an important protective effect against the thermal bridging caused by the fastener.Next, we found that the steel deck made a big difference as well. In the physical experiment, the air contained in the flutes of the steel deck added to the R-value of the assembly, while the computer simulation did not account for this effect. That's an item that needs to be addressed in the next phase of research. Despite this anomaly, both approaches showed the same thing: steel deck acts like a radiator, exacerbating the effect of the fastener. In the assemblies with just ISO and steel deck (Cases III), adding a fastener resulted in an R-value drop of 11 % for the physical experiment and 4,6 % for the computer simulation compared to the assembly with no fastener.Finally, the assemblies with all the components (HD ISO, ISO and steel deck, a.k.a. Cases IV) showed again that the HD ISO insulated the fastener and reduced its negative impact on the R-value of the overall assembly. The physical experiment had a 6,1 % drop (down from 11 % with no cover board!) and the computer simulation a 4,2 % drop (down from 4,6 % with no cover board) in R-value when the fastener was added.What Does This Study Tell Us?The morals of the study just described are these:Roof fasteners have a measurable impact on the R-value of roof insulation.High-density polyisocyanurate cover boards go a long way toward minimizing the thermal impacts of roof fasteners.Steel deck, due to its high conductivity, acts as a radiator, amplifying the thermal bridging effect of fasteners.What Should We Do About It?As for figuring out what to do about it, this study and others first need to be extended to the real world, and that means making assumptions about parameters like the siting of the building, the roof fastener densities required, and the roof assembly type.Several groups have made this leap from looking at point thermal bridges to what they mean for a roof's overall performance. The following example was explored in a paper by Taylor, Willits, Hartwig and Kirby, presented at the RCI, Inc. Building Envelope Technology Symposium in 2018. In that paper, the authors extended computer simulation results from a 2015 paper by Olson, Saldanha, and Hsu to a set of actual roofing scenarios. They found that the installation method has a big impact on the in-service R-value of the roof.They assumed a 15,000-square-foot roof, fastener patterns and densities based on a wind uplift requirement of 120 pounds per square foot, and a design R-value of R-30. In this example, a traditional mechanically attached roof had an in-service R-value of only R-25, which is a 17 % loss compared to the design R-value.An induction-welded roof was a slight improvement over the mechanically attached assembly, with an in-service value of only R-26,5 (a 12 % loss compared to the design R-value).Adhering instead of fastening the top layer of polyiso resulted in an in-service R-value of R-28,7 (a 4 % loss compared to the design R-value).Finally, in their study, an HD polyiso board was used as a mechanically fastened substrate board on top of the steel deck, allowing both layers of continuous polyiso insulation and the roof membrane to be adhered. Doing so resulted in an in-service R-value of R-29.5, representing only a 1,5 % loss compared to the design R-value.To operationalize these findings in your own roofing design projects, consider the following approaches:Consider eliminating roof fasteners altogether, or burying them beneath one or more layers of insulation. Multiple studies have shown that placing fastener heads and plates beneath a cover board, or, better yet, beneath one or two layers of staggered insulation, such as GAF's EnergyGuard™ Polyiso Insulation, can dampen the thermal bridging effects of fasteners. Adhering all or some of the layers of a roof assembly minimizes unwanted thermal outcomes.Consider using an insulating cover board, such as GAF's EnergyGuard™ HD or EnergyGuard™ HD Plus Polyiso cover board. Installing an adhered cover board in general is good roofing practice for a host of reasons: they provide enhanced longevity and system performance by protecting roof membranes and insulation from hail damage; they allow for enhanced wind uplift and improved aesthetics; and they offer additional R-value and mitigate thermal bridging as shown in our recent study.Consider using an induction-welded system that minimizes the number of total roof fasteners by dictating an even spacing of insulation fasteners. The special plates of these fasteners are then welded to the underside of the roof membrane using an induction heat tool. This process eliminates the need for additional membrane fasteners.Consider beefing up the R-value of the roof insulation. If fasteners diminish the actual thermal performance of roof insulation, building owners are not getting the benefit of the design R-value. Extra insulation beyond the code minimum can be specified to make up the difference.Where Do We Go From Here?Some work remains to be done before we have a computer simulation that more closely aligns with physical experiments on identical assemblies. But, the two methods in our recent study aligned within a range of 0,8 to 6,7 %, which indicates that we are making progress. With ever-better modeling methods, designers should soon be able to predict the impact of fasteners rather than ignoring it and hoping for the best.Once we, as a roofing industry, have these detailed computer simulation tools in place, we can include the findings from these tools in codes and standards. These can be used by those who don't have the time or resources to model roof assemblies using a lab or sophisticated modeling software. With easy-to-use resources quantifying thermal bridging through roof fasteners, roof designers will no longer be putting building owners at risk of wasting energy, or, even worse, of experiencing condensation problems due to under-insulated roof assemblies. Designers will have a much better picture of exactly what the building owner is getting when they specify a roof that includes fasteners, and which of the measures detailed above they might take into consideration to avoid any negative consequences.This research discussed in this blog was conducted with a grant from the RCI-IIBEC Foundation and was presented at IIBEC's 2023 Annual Trade Show and Convention in Houston on March 6. Contact IIBEC at https://iibec.org/ or GAF at BuildingScience@GAF.com for more information.

By Authors Elizabeth Grant

17 novembre 2023

Apples and pears in crates ready for shipping. Cold storage interior.
Science du bâtiment

Conception de toit pour chambre froide : 5 composants clés d'un système de toiture étanche

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This vapor drive can have detrimental effects on the roof assembly, including condensation within the assembly, leading to deterioration and potential failure if not properly addressed. Similarly, uncontrolled air movement between the warm exterior to the cold interior can lead to condensation within the roof assembly and at the underside of the roof deck. Condensation occurs when the warm, humid exterior meets the cold interior air and most often occurs at the roof to deck interface and at penetrations where there are discontinuities in the roof assembly.Key Components in Creating an Air-Tight Roof SystemTo achieve a high performing airtight roof system, it is crucial to focus on the entire roof system including: selection of the membrane, insulation, coverboards, roof attachment methods, and detailing at penetrations, curbs, and roof decks to wall interfaces. While each of these components play a vital role in preventing air leakage, thermal loss, and condensation in cold storage facilities, it is the proper design and detailing of the entire assembly that makes a successful cold storage roof installation.Membrane Selection:When selecting a roof membrane, it's essential to consider factors such as seam strength, puncture resistance, and air and vapor retarding properties. Single-ply membranes with heat-welded seams provide better long-term performance than taped or glued seams, as they create a monolithic material and the seam becomes the strongest point of the membrane. In conjunction with a coverboard, on roofs where contractor access is required for servicing units, such as for glycol or ammonia lines on cold storage facilities, a thicker membrane that can withstand added foot traffic is preferred. Additionally, for cold storage buildings located in hail zones, a thicker membrane or a fleece-back membrane, coupled with a coverboard, will provide additional protection from the storm. Most roofing membranes function as both an air and vapor retarder; a properly installed and detailed roof membrane can help minimize condensation potential and improve the overall performance of the roof. The most effective place for a vapor retarder in a cold storage facility is at the exterior of the roofing assembly as vapor drive will be from the warm exterior to the cooler interior. A roof membrane acts at the vapor retarder and can also limit uncontrolled air from the exterior to the interior when detailed properly. Asphaltic systems, due to the multiple layers and the granule surface, limit air and vapor flow due to the nature of the multi-ply installation, and are generally more resistant to punctures than thinner single-ply systems.Insulation:Insulation is crucial for maintaining ideal temperature levels and promoting energy efficiency in cold storage buildings. Adhering to both the Energy Code and industry standards, such as insulation recommendations by ASHRAE, the appropriate amount of insulation should be used; the colder the interior temperature, the additional insulation that may be required. Often blast freezers have interior temperatures that can be as low as -50℉ and will have up to R60 of roof insulation. Ensuring proper insulation thickness, including a minimum of two layers of insulation and staggering and offsetting the insulation joints, will mitigate thermal loss between board joints.Coverboards:Coverboards provide added protection against foot traffic and other potential hazards, such as damage from weather related events, to the roof system. Coverboards provide protection to the insulation as well as stiffen the substrate beneath the membrane. The use of appropriate coverboards can significantly improve the durability and lifespan of the roof system including an ability to mitigate damage to the membrane from hail or flying debris. Additionally, by installing a coverboard, the roof system becomes more resilient to damage. This means less repairs or noise making activities to complete the repairs after a storm, and less downtime at the interior of the building if the damage is significant. The addition of a coverboard is considered a best practice in a roofing assembly, and the incorporation of the coverboard beneath the membrane will increase overall system robustness.Roof Attachment Methods:The attachment method plays a vital role in minimizing thermal bridging and improving overall energy efficiency, whether through mechanical fasteners or adhesive attachment options. It is recommended to install an adhered system, of either typical adhesives or asphaltic systems, which mechanically attaches the first layer of insulation and adheres subsequent layers. Burying the fasteners in the insulation layer closest to the roof deck decreases the effects of thermal bridging and thermal loss. Burying the fasteners also eliminates potential air paths created by fasteners throughout the roof system.Detailing at Penetrations, Curbs, and Steel Decks:Detailing at penetrations and at exterior wall to roof deck interfaces is an essential aspect of ensuring an airtight roof system. Proper air sealing at these critical points, which includes the installation of closed cell spray foam, can help prevent uncontrolled air movement and ultimately condensation within the roof system. At steel roof decks, closed cell spray foam should be installed in deck flutes a minimum of 12-inches measured from the exterior walls, around penetrations, and at roof dividing walls. Closed cell spray foam should also be installed a minimum 1-inch between the joint and the rigid insulation at roof to exterior wall interfaces and penetrations.Designing and installing an airtight roof assembly is critical in cold storage facilities. Improper design or installation can leave voids in the system that allow for the warm exterior air to meet with the cooler interior air, causing condensation within the roofing system, which can lead to premature deterioration of roof components. Installing a robust roof assembly, including consideration to the membrane thickness, coverboard, insulation, and attachment method impacts the service life and resiliency of the membrane.Curious to learn more about cold storage buildings and the critical role roofing plays? Explore the GAF Cold Storage website, read A Guide to Cold Storage Roof System Design, connect with the GAF Building & Roofing Sciences team, or send an email to coldstorage.assistance@gaf.com for additional information.

By Authors Kristin Westover

10 novembre 2023

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