RoofViews

Commercial Roofing

Professional Roof Maintenance Protects Your Building and Your Business

By Don Kilcoyne

June 18, 2021

Roof inspection in progress

Your roof is the great unsung hero of both your building envelope and your bottom line. Although it's rarely seen, it's constantly under assault from the elements, including rain, wind, extreme cold and heat, UV rays, contaminants, and more. And it forms the first line of defense against unexpected and unwanted expenses.

Like tossing a stone into a still river, postponing roof maintenance can drive financial ripples throughout your entire business, from shortening the longevity of the roof itself to disrupting business, employees, and tenants.

On the other hand, making sure your roof receives professional roof maintenance can pay off in ways you may never have expected. Perhaps the greatest benefit of a regular maintenance program is the chance to catch issues early and while they are still repairable. This can help extend the time between re-roofs and maximize the value of your investment. But that's just the start.

Let's start at the top. Regular, professional commercial roof maintenance can help protect your roof investment by giving you a chance to:

  • Identify small problems, like loose flashings, clogged drains, standing water, and so on, before they become expensive issues
  • Prevent accumulation of chemical contaminants that may harm the roof membrane
  • Remove wind-blown debris that can damage, or even puncture, the roof
  • Keep reflective surfaces clean so they can provide maximum reflectivity
  • Remove organic debris that can provide a food source for destructive algae, plants, birds, and four-legged pests
  • Meet the owner maintenance requirements in GAF guarantees
  • Potentially qualify your roof for the GAF WellRoof Guarantee Extension, which extends the duration of GAF Diamond Pledge™ NDL Roof Guarantees by up to 25% for eligible roofs (additional requirements and restrictions apply)

Below the roof, professional maintenance can help prevent lost revenue from:

  • Damage to building contents
  • Dissatisfied tenants
  • Premises liability exposure
  • Reduced space as leaks put rooms or floors out of service
  • Equipment downtime
  • Potential energy loss caused by wet/deteriorated insulation

It's important to keep in mind that one storm can alter the condition of your roof in a matter of hours. Having a professional inspect right away for debris, water, clogged drains, loosened flashings, and wind uplift can often mean the difference between a simple clean-up and an expensive repair.

If you'd like to set up a preventative maintenance program, please visit us.gaf.com/TalkToGAF.

About the Author

Don Kilcoyne, a writer and editor for GAF, crafts marketing campaigns and language that communicate the company brand, initiatives, products, and priorities in video, print, and social media, as well as GAF Roof Views. He joined the GAF team in late 2016, bringing a background as a creative director and author.

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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. And, unlike the discretionary nature of some flights and the often optional decision to use furnishings like wallpaper, heating and cooling are necessary for the functioning of almost all occupied buildings.Based on this example, you can consider building products with operational benefits, like insulation, as an "investment." It is appropriate to look at improving the building enclosure and understanding what the return on the investment is from a carbon perspective. As the comparison above demonstrates, if you have a limited supply of carbon to "invest", putting it into more roof insulation is a very smart move compared to "spending" it on a discretionary flight or on a product without use-phase carbon benefits, such as wallpaper.This means we should be careful not to measure products like insulation that save CO2e in the building use-phase savings only by their embodied carbon use, but by their total carbon profile. 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/

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