RoofViews

Science du bâtiment

How to Choose the Best Membrane for a Commercial Solar Power Installation

By Thomas J Taylor

29 février 2016

Solar installation on a commercial roof

At the end of 2014, there were 16 000 megawatts (MW) of installed solar power capacity in the U.S. Of that, around 4 750 MW were from commercial PV installations, which include low-slope rooftop installations (the remaining was from residential and utility installations). There is little doubt that solar power has become significant; in comparison, coal-fired power plants typically are between 400 to 600 MW each. Also, because efficiency is a factor, the most efficient U.S. coal-fired plant is right around 40 % (the John W. Turk Plant in Arkansas).

Looking at past trends of solar installations as shown in the chart below, it's clear that we can expect continued rapid growth and falling solar costs that will help grow and expand the solar market.

chart

Although it varies depending on local circumstances, overall today, the cost of solar power has become competitive with traditional generation.

So, how do our roofing membrane choices play into this? There are several things to consider when selecting a membrane for a roof that might have a solar installation added.

Facilité d'installation

Typical single-ply roofs have even surfaces that can be easily marked off and worked on during a solar installation. Wide and long sheets mean there are fewer seams and smooth surfaces mean that installers can rapidly get attachments and flashings installed.

Long-Term Roof Performance

No one wants to have to repair a roof that has a large solar array overburden. However, if the membrane is a multi-ply system, the job of even finding a leak gets exponentially harder. Solar arrays can't be "moved out of the way"-they are permanent and restrict access to the membrane. This again points to why single-ply membranes are the best choice.

However, membrane choice also comes down to the expected lifetime of the array versus that of the roof. Many studies have shown that solar arrays could be producing power well beyond 25 years. That makes it important to select a supplier and membrane type that can offer confidence in weathering resistance. EverGuard Extreme® is a good example of a membrane designed for long-term weather resistance, backed by an industry-leading warranty.

Solar Array Efficiency

The temperature of solar panels is a significant factor affecting how much electricity the panels produce. This is generally measured by the "temperature coefficient" of the solar panels, which is the percentage loss in efficiency per degree rise in temperature. So, as panels get hotter, they produce less power.

As listed on solar panel spec sheets, the power efficiency of an average panel is 16,21 % at 111,2°F (45°C) and the "maximum power temperature coefficient" is -0,42 % per °C. This means that the panel would lose 0,42 % of its power output for every 1°C rise in rooftop temperature above 45°C (111,2°F). So, let's take a look at what that means for some typical roofs:

The GAF EverGuard Extreme® TPO membrane was designed to substantially reduce rooftop temperature. For instance, on a sunny day with an ambient air temperature of 89°F (32°C), the roof temperature measured on an EPDM, dark roof was 173°F (78°C), resulting in a 13,86 % decrease in energy efficiency from the standard system; the roof temperature measured on an EverGuard Extreme® TPO roof was only 116°F (46,6°C), resulting in a decrease of only 0,67 % in energy efficiency.

Of course, this is approximate because the air temperature around the panels might be slightly lower. However, it's clear that reflective membranes can result in more power output from solar arrays. This has actually been demonstrated in independent tests. So, typically we would expect the efficiency of a solar array to be about 13 % higher when installed over a highly reflective membrane such as EverGuard Extreme® TPO, compared to a dark membrane with low reflectance.

Long-Term Membrane Reflectance

The reflectivity of a rooftop membrane is established through certifications by institutions such as the Cool Roof Rating Council (CRRC) or the ENERGY STAR® rating program administered by the Department of Energy and the Environmental Protection Agency. CRRC publishes searchable radiative data online. The reflectivity (Total Solar Reflectance or TSR) is the fraction of sunlight that a surface reflects and is measured on a scale of 0 to 1 (for example, a surface that reflects 55 % of sunlight has a total solar reflectance of 0,55). According to the CRRC, the initial TSR for a typical dark EPDM membrane is a paltry 0,06 (or 3-year aged TSR of 0,07), while the TSR for the EverGuard Extreme® TPO roof is 0,835 (or 3-year aged TSR of 0,73)!

The following is a picture of a TPO roof with a solar array in New Jersey installed over 5 years ago.

solar1

The roof has never been cleaned, as can be seen by the dirt under the panels. But, where the membrane is fully exposed, rain has kept the membrane white and reflective. Clearly, based on their reflectivity, ease of maintenance, and longevity, white TPO membranes are the best choice for these applications.


Lead photo credit: Sanko Fukaya Factory Administrative Office

About the Author

Thomas J Taylor, Ph. D. est le conseiller scientifique de la science de la construction et de la toiture de GAF. Tom compte plus de 20 ans d'expérience dans l'industrie des produits de construction à travailler pour des entreprises manufacturières. Il a obtenu son doctorat en chimie à l'University of Salford, en Angleterre, et détient environ 35 brevets. Chez GAF, Tom se consacre principalement à la conception de systèmes de toiture et à la réduction de la consommation d'énergie des bâtiments. Sous la direction de Tom, GAF a développé un TPO avec une résistance aux intempéries inégalée.

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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? 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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

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