RoofViews

Science du bâtiment

Comment les architectes peuvent compter sur les services de conception de toit pour la réussite des projets

By Karen L Edwards

22 novembre 2022

Roof design services team

Architects strive to achieve a roof design that will perform well and meet project-specific requirements. That often means incorporating the building code and warranty/guarantee requirements that building owners must meet - among the most important factors of any construction project - into the design. La tâche n'est pas facile, en particulier avec le très grand nombre de systèmes de toiture disponible. Even experienced architects can find it challenging to get familiar with all available components and identify which materials are going to be suitable for a particular building.

Enter the GAF Design Services Team. Formed by merging together three different departments — field services, technical support services, and architectural information services — these technical professionals help support architects in delivering high-performing roofing systems that meet project-specific requirements.

Support from Start to Finish

As GAF Senior Design Services Specialist Jesse Caruso explains, "The goal of Design Services is to essentially combine all three of those tasks into one large service team that assists architects, engineers, specifiers, consultants, sales reps, and contractors achieve their roof design goals. From the moment someone says they need a new roof, we are there throughout the entire process to provide support, all the way until the end of that roof guarantee."

Each region of the country has dedicated Design Services personnel just a phone call away, ready to provide information about GAF commercial roofing systems. They understand the unique needs of different geographic areas of the country.

"We help walk a contractor or an owner or architect through that entire roofing lifecycle," says Caruso. "From how to install the system to what kind of warranty or guarantee you're going to get and how to maintain that guarantee or warranty."

Texas Staff

GAF's Port Arthur, TX Design Services Team: Dacia Belt, Nathan Vidrine, Shelby Noland, Brittany Castillo, Stephanie Lawrence, Melissa Vaughan, Traci Hicks, Jessica Crabtree, Traci Smith, Melanie Miller, Shelly Benoit, & Brittany Sanchez

Some of the topics Caruso's team is asked to assist with most frequently include:

  • Product Testing: The Design Services team can confirm and provide documentation that shows which products and systems meet ASTM or UL standards for fire and hail resistance. They can also verify wind uplift ratings and other special approvals, such as Factory Mutual and Miami-Dade approvals.
  • Installation Guidelines: The team can provide data on how different methods of installation can affect roofs' performance and guarantees. For instance, if a building is in a coastal area and needs a higher wind uplift rating, the team can provide guidance on fastening patterns and other installation strategies that will help meet that wind uplift requirement.
  • Guarantee Terms: One of the most important aspects for building owners to consider is the warranty or guarantee protection provided by the roofing manufacturer. The Design Services team can assist by verifying what types of coverage are available and what contractor certifications are necessary to deliver a certain type of warranty or guarantee.
  • Documentation: The team can provide professional documentation that supports product testing, ratings, and warranty/guarantee information. One submittal package may contain design lines, cut specs, system letters, data sheets, and more. This documentation can provide assurance from the manufacturer that the roof system will meet or exceed project requirements.

An Architect's Partner for Success

No matter what challenges professionals may encounter while designing a new roofing system, the GAF Design Services Team is there to assist. You can be confident that the finished roofing system will provide the desired performance and protect the building for years to come.

Reach out to the team by emailing designservices@gaf.com or visiting the design professionals help page.

About the Author

Karen est une rédactrice indépendante pour le secteur de la construction et sa passion pour les toitures l'a motivée au cours de ses 20 ans de travail dans le secteur.

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Installation of ISO Board and TPO on a Roof
Science du bâtiment

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Your choices here are expanded over the previous example of an airplane flight. You can limit CO2 by choosing a product with a long useful life. You can also apply the three Rs: reduce the quantity of new product used, reuse existing material when possible, and recycle product scraps at installation and the rest at the end of its lifespan. In the final step in our thought experiment, consider the insulation in your client's building. As before, we must generate a certain amount of CO2e to create a durable good. In this case, it's one with use-phase benefits. Insulation can reduce operational energy by reducing heat flow through the building enclosure, reducing the need to burn fuel or use electricity to heat and cool the building. The good news is that, in addition to the other strategies considered for the flight and the wallpaper, here you can also maximize operational carbon savings to offset the initial embodied carbon input. 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So, how do we calculate this?Putting It to the TestWe were curious to know just how much operational carbon roof insulation could save relative to the initial investment of embodied carbon required to include it in a building. To understand this, we modeled the US Department of Energy's (DOE) Standalone Retail Prototype Building located in Climate Zone 4A to comply with ASHRAE 90,1-2019 energy requirements. We took the insulation product's embodied energy and carbon data from the Polyisocyanurate Insulation Manufacturers Association's (PIMA) industry-wide environmental product declaration (EPD).To significantly reduce operational carbon, the largest carbon challenge facing buildings today, the returns on the investment of our building design strategies need to be consistent over time. This is where passive design strategies like building enclosure improvements really shine. They have much longer service lives than, for example, finish materials, leading to sustained returns.Specifically, we looked here at how our example building's roof insulation impacted both embodied and operational carbon and energy use. To do this, we calculated the cumulative carbon savings over the 75-year life of our model building. In our example, we assumed R-30 insulation installed at the outset, increased every 20 years by R-10, when the roof membrane is periodically replaced.In our analysis, the embodied CO2e associated with installing R-30 (shown by the brown curve in years -1 to 1), the embodied carbon of the additional R-10 of insulation added every 20 years (too small to show up in the graph), and the embodied carbon represented by end-of-life disposal (also too small to show up) are all taken into account. About five months after the building becomes operational, the embodied carbon investment of the roof insulation is dwarfed by the operational savings it provides. The initial and supplemental roof insulation ultimately saves a net of 705 metric tons of carbon over the life of the building.If you want to see more examples like the one above, check out PIMA's study, conducted by the consulting firm ICF. The research group looked at several DOE building prototypes across a range of climate zones, calculating how much carbon, energy, and money can be saved when roof insulation is upgraded from an existing baseline to current code compliance. Their results can be found here. Justin Koscher of PIMA also highlighted these savings, conveniently sorted by climate zone and building type, here.Support for Carbon Investment DecisionsSo how can you make sure you address both operational and embodied carbon when making "carbon investment" decisions? We've prepared a handy chart to help.First, when looking at lower-embodied-carbon substitutions for higher-embodied-carbon building materials or systems (moving from the upper-left red quadrant to the lower-left yellow quadrant in the chart), ensure that the alternatives you are considering have equivalent performance attributes in terms of resilience and longevity. If an alternative material or system has lower initial embodied carbon, but doesn't perform as well or last as long as the specified product, then it may not be a good carbon investment. Another consideration here is whether or not the embodied carbon of the alternative is released as emissions (i.e. as part of its raw material supply or manufacturing, or "cradle to gate" stages), or if it remains in the product throughout its useful life. In other words, can the alternative item be considered a carbon sink? If so, using it may be a good strategy.Next, determine if the alternative product or system can provide operational carbon savings, even if it has high embodied energy (upper-right yellow quadrant). If the alternative has positive operational carbon impacts over a long period, don't sacrifice operational carbon savings for the sake of avoiding an initial embodied product carbon investment when justified for strategic reasons.Last, if a product has high operational carbon savings and relatively low embodied carbon (lower-right green quadrant), include more of this product in your designs. The polyiso roof insulation in our example above fits into this category. You can utilize these carbon savings to offset the carbon use in other areas of the design, like aesthetic finishes, where the decision to use the product may be discretionary but desired.When designing buildings, we need to consider the whole picture, looking at building products' embodied carbon as a potential investment yielding improved operational and performance outcomes. Our design choices and product selection can have a significant impact on total carbon targets for the buildings we envision, build, and operate.Click these links to learn more about GAF's and Siplast's insulation solutions. Please also visit our design professional and architect resources page for guide specifications, details, innovative green building materials, continuing education, and expert guidance.We presented the findings in this blog in a presentation called "Carbon and Energy Impacts of Roof Insulation: The Whole[-Life] Story" given at the BEST6 Conference on March 19, 2024 in Austin, Texas.References:Architecture 2030. (2019). New Buildings: Embodied Carbon. https://web.archive.org/web/20190801031738/https://architecture2030.org/new-buildings-embodied/ Carbon Leadership Forum. (2023, April 2). 1 - Embodied Carbon 101. https://carbonleadershipforum.org/embodied-carbon-101/

By Authors Elizabeth Grant

Le 18 septembre 2024

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