polyiso

Why insulate the exterior side of the foundation wall?

All building foundations come in contact with the ground. Wherever a building is located, water, temperature, air, and soil on the foundation can impact the performance and integrity of the total structure. Continuous polyiso rigid foam insulation effectively reduces foundation energy loss and protects against moisture problems.

ADVANTAGES OF INSULATING
EXTERIOR VS. INTERIOR SIDE OF THE WALL

  • It does not reduce the usable building space

  • Completely continuous for optimal energy efficiency

  • Mass of foundation within the insulated building envelope

  • Warm wall solution minimizes condensation on the interior side of the wall

  • Protects the waterproofing

  • Eliminates freeze/thaw on structural elements

  • Easiest install

Foundation Wall Insulation

Supply chain woes? Don’t compromise on the long-term benefits of building energy efficiency.

Posted By PIMA

To solve today’s supply chain challenges, should we ignore the building energy code? No, accepting less today in return for higher costs tomorrow is no strategy at all.

The inconvenient truth for critics of building energy codes is that compliance with current versions of the IECC and ASHRAE 90.1 serves as the most cost-effective mechanism for reducing building energy use and the associated carbon emissions generated from powering schools, office buildings and other commercial spaces. While today’s supply chain challenges are certainly frustrating, ignoring the energy code eliminates long-term improvements in building energy efficiency and saddles building owners with higher energy costs for decades to come.

Energy codes provide minimum standards for new and existing buildings. One way the codes help improve the performance of existing buildings is by requiring that roof replacement projects comply with code minimums for building envelope insulation. A recent study by PIMA and the consulting firm ICF International confirmed that energy code-compliant roof replacements are life-cycle economical under various conditions even when subjected to higher incremental installation costs and discount rates. For example, a primary school located in Climate Zone 5 (Chicago) can experience an estimated 9% savings in annual whole building energy use by installing a roof replacement with code-compliant levels of insulation. These savings will continue to compound year-over-year during the roof’s service life.

Simple, short-term solutions can be appealing in times of duress. In the case of building energy efficiency improvements, a short-term focus that sacrifices long-terms benefits is a bad deal for building owners. Check out the PIMA study for more information on how installing an energy efficient roof today is the right decision for your project or building.  

Excited to be part of the ABAA Education Webinar Event on December 30th!!

REGISTER for our, “Polyiso: The Next Generation Air & Water Resistive Barrier” CE webinar, available through ABAA Education Webinar Events.

FREE LIVE CEU WEBINAR - NOVEMBER 30TH!

This course is designed to provide an understanding of how better construction practices can increase building sustainability and longevity. Discover how polyiso insulation air and water-resistive barrier systems contribute to meeting energy code requirements and outperform traditional water-resistive barrier materials and construction methods. Learn about the science behind thermal, air, and moisture control, in projects of steel stud construction. Review building and energy code requirements relative to building envelope design and performance.


LEARNING OBJECTIVES: 

  1. Understand Building Sustainability and Longevity

  2. Learn About the Science Behind Thermal, Air, and Moisture Control for Steel Stud Construction

  3. Interpret the Code Requirements for Building Envelope Design and Performance

  4. Discover How Polyiso Meets Requirements and Outperforms Traditional Methods for Optimum Control


Sponsored By: Rmax

Presented By: Matt Stevens


Matthew Stevens, CSI, CDT, REWO received his Master’s degree in Architecture from Texas Tech University and has over 20 years in the building industry. His experience includes architectural design, construction, consulting, training, and development roles. As the Commercial Envelope Specialist for Rmax, he works directly with architects and contractors to select the optimal insulation for their projects while meeting applicable building codes. Matthew is an active member that serves on the boards of several CSI and BEC chapters in Texas.




Why is Proper Insulation Critical During Building Roof Replacement?


The Benefits of Energy Code-Compliant Roof Replacement

For U.S. Climate Zone 5 – Chicago, IL

PIMA_Roof-Replacement-Cold-Climates_Fact-Sheet_RoofingImage.png

Insulation, whether in a public or commercial building, has a tremendous impact on the energy efficiency, resilience, cost savings, and comfort of a space. While insulation can be an inconspicuous and sometimes overlooked building feature, it spans the entire surface area of a building’s roof and helps to protect other aspects of building performance.

Roof insulation is particularly important for building performance as the roof comprises the largest single side of most buildings. Recognizing the importance of an energy-efficient building thermal envelope, modern energy codes have set minimum requirements for insulation installed entirely above the roof deck.

For low-slope roofs with insulation entirely above deck, which is typical of public and commercial buildings, standards require that roof insulation be installed in multiple layers with staggered joints to reduce airflow through gaps and require that it meets the prescribed minimum R-value requirement for the building’s climate zone, space conditioning category, and roof construction type.


Finding the Right Insulation for U.S. Climate Zone 5

When selecting the proper roof insulation for your building, it is critical to consider the climate zone for your location. Cities located in U.S. Climate Zone 5 are characterized as cold climates, which is defined as an area with between 5,400 and 9,000 heating degree days on a 65 degrees Fahrenheit basis.

U.S. Climate Zone 5 - Cold Climates I Example City – Chicago, IL

PIMA_Roof-Replacement-Cold-Climates_Fact-Sheet_Climate-Zone-Map.png

Potential Savings Estimates for Buildings in Climate Zone 5

During a roof replacement, installing additional roof insulation to meet the prescribed minimum R-value established by building energy standards for your region is estimated to yield cost savings and enhance overall performance for each of the building types modeled below. For buildings located in Climate Zone 5, current model energy codes require a minimum R-30 for roof insulation installed entirely above the deck.

PIMA_Roof-Replacement-Cold-Climates_Fact-Sheet_SavingsChart.png

In cold climate zones where building energy expenditure is often dominated by heating processes, an inefficient thermal building envelope can waste gas and electricity, generating unnecessarily high utility bills.

The estimated payback of using code-compliant levels of insulation at the time of roof replacement can help companies and building owners realize a faster return on investment, while also locking in long-term energy savings at no additional operation and maintenance cost for the life of the investment – typically 30 to 40 years. The result is greater cost savings, improved building performance, and downstream emissions benefits, as well as decreased risk and the likelihood of premature maintenance and repairs. When viewed as a long-term investment, code-compliant levels of roof insulation entirely above deck can help companies reach energy reduction goals while cutting costs and carbon emissions in the process.

This analysis was prepared by ICF. For more information on insulation and to access the full report, visit www.polyiso.org.

SAVE YOUR FREE SEAT TO EARN LU/AIA CEH!

This course is designed to provide an understanding of how better construction practices can increase building sustainability and longevity. Discover how polyiso insulation air and water-resistive barrier systems contribute to meeting energy code requirements and outperform traditional water-resistive barrier materials and construction methods. Learn about the science behind thermal, air, and moisture control, in projects of steel stud construction. Review building and energy code requirements relative to building envelope design and performance.


LEARNING OBJECTIVES: 

  1. Understand Building Sustainability and Longevity

  2. Learn About the Science Behind Thermal, Air, and Moisture Control for Steel Stud Construction

  3. Interpret the Code Requirements for Building Envelope Design and Performance

  4. Discover How Polyiso Meets Requirements and Outperforms Traditional Methods for Optimum Control


Sponsored By: Rmax

Presented By: Matt Stevens


MattStevens.jpg

Matthew Stevens, CSI, CDT, REWO received his Master’s degree in Architecture from Texas Tech University and has over 20 years in the building industry. His experience includes architectural design, construction, consulting, training, and development roles. As the Commercial Envelope Specialist for Rmax, he works directly with architects and contractors to select the optimal insulation for their projects while meeting applicable building codes. Matthew is an active member that serves on the boards of several CSI and BEC chapters in Texas.




FREE CEU Webinar...Don't miss out!


AIA Course Number: WRX08A

GBCI Course ID: 0920017060

Sponsored By: Rmax

Presented By: Matthew Stevens, CSI, CDT

Matthew Stevens, CSI, CDT, received his Master’s degree in Architecture from Texas Tech University and has over 20 years in the building industry. His experience includes architectural design, construction, consulting, training and development roles. As the Commercial Envelope Specialist for Rmax, he works directly with architects and contractors to select the optimal insulation for their projects while meeting applicable building codes. Matthew is an active member that serves on the boards of several CSI and BEC chapters in Texas.

Codes, Standards & Performance...

Continuous Insulation Performance: Today’s Codes and Standards Achieve Energy Efficiency and Fire Performance.

Posted By PIMA

Building occupant safety is always a top priority and can be harmoniously incorporated into building designs that strive to meet elevated targets for other performance attributes, including energy efficiency.

A recent article by PIMA’s Marcin Pazera in Construction Specifier highlights the fire-safety measures required by today’s building codes (e.g. fire suppression systems, building egress requirements, fire-resistive assemblies, and construction material fire test standards) and the tools professionals can use to achieve a balanced approach to fire safety and energy efficiency in buildings.

The intersection of fire safety and energy efficiency within exterior walls of commercial buildings is a topic that is receiving well-deserved attention. Incorporating polyiso continuous insulation in the design for commercial walls can help design professionals achieve these twin goals. In his article, Mr. Pazera explains how today’s building codes use performance-based testing to establish minimum criteria for the fire performance of wall assemblies. In particular, the article highlights the compliance requirements for NFPA 285 – Standard Fire Test Method for Evaluation of Fire Propagation Characteristics of Exterior Wall Assemblies Containing Combustible Components – under the International Building Code.

You can read the article here.

Great Article!! Great Read!! Below-Grade Applications and Polyiso Insulation

Protecting Walls and Foundations with Below-Grade Polyiso Insulation

Article by, Marcin Pazera, Ph.D., Technical Director for Polyisocyanurate Insulation Manufacturers Association (PIMA).

Design-Lateral-Soil-Load_PSI-Illustration.02-19-2021.jpg

By their very nature, all building foundations touch the earth that surrounds them. In every climate, the water, air, soil, and temperature of that outside contact can impact the performance and integrity of the entire building structure. A variety of insulation products and water-resistant surface treatments are available to mitigate moisture problems with below-grade walls.

Polyiso

Polyisocyanurate (“polyiso”) boards are some of the most popular insulation products on the market today. Made of water-resistant rigid foam sandwiched between two protective facers, polyiso insulation is commonly used on commercial and residential roofs and walls because of its high R-value per inch of thickness, its capacity to serve as a vapor retarder, low water absorption, high compressive strength and durability, and ease of handling.

What many builders don’t realize is that, depending on facer type used, polyiso can also be used in below-grade applications in both commercial and residential buildings to protect basement and foundation walls. A common misconception in the construction field is that polyiso is not suited for use below grade because it is frequently produced with all paper facers that can absorb moisture. Some builders turn instead to other products like extruded polystyrene (XPS) or expanded (EPS) polystyrene that require more material to achieve the same R-value. Polyiso, which is itself water-resistant because of its closed-cell structure, is also sold with durable, non-absorbing facers – aluminum foil facers and coated glass facers – that are appropriate for moist environments such as below-grade applications. 

Polyiso is manufactured through a continuous lamination process in which the liquid raw materials that make up the foam formulation are mixed, causing a rapid chemical reaction that transforms them into a rigid and thermally stable polymeric closed-cell structure. This foam is laid between the two facer materials, and travel through a laminator allowing for initial curing. The laminator can be adjusted to produce different thickness boards, which are then trimmed and cut into various lengths, typically 4’ x 8’ size but can be customized for specific project requirements to fit engineering guidelines. These closed-cell, rigid foam boards are consistently rated as economical and easy to install.

[R-value measure 180 days]

Compressive Strength

In addition to its high thermal performance, polyiso is noted for its compressive strength. Below grade, the soil that is backfilled against a foundation exerts lateral pressure on the foundation and below-grade walls. Soil weight presses downward and exerts lateral pressure. As an example, a well-drained soil can have a lateral load of 1,250psf at 10 foot-depth below grade and 1,875 psf at 15 feet below grade.  Undrained soil systems can have a lateral load of 1,874 psf and 2,811 psf, respectively. Insulation or drainage materials without sufficient compressive strength are unable to resist this pressure and compress, reducing R-value and compromising drainage.  Available in 16psi (2,300 psf), 20psi (2,880 psf) and 25psi (3,600 psf), polyiso board insulation has the compressive strength to resist soil pressures.

 

Water-resistant Boards

Some builders may be hesitant to use polyiso below grade because they worry about damage to the facer during the backfill process. It is important to realize that, while the various facers do provide some added benefits to the boards, the foam itself is water-resistant because the chain reaction creates a closed cell that does not absorb water. As long as the concrete behind it is adequately waterproofed and the polyiso boards are properly installed with tight joints, its performance would not be compromised by incidental damage to the facer sustained during the installation process.

 

Use Above Frost Line

Polyiso insulation can also be used as part of a  much shallower foundation, which saves on building costs. Building codes require that foundations extend below the local frost line. In cold climates, this can mean a foundation is more than 5’ below grade. However, Polyiso insulation protects the foundation from freezing at shallower depths than the prescribed local frost line.

Though most builders think of polyiso as a product commonly used  in low-slope commercial roofs, its consistently excellent performance has expanded its market share in applications on roofs and walls of all kinds in both commercial and residential projects. Its effective use in below-grade applications has an established history in Europe and is becoming increasingly more common here in the United States and Canada.

Polyiso manufacturers continue to rigorously test products by third-party independent laboratories for physical properties, fire and thermal performance as well as assess environmental impacts. Information is available from manufacturers of polyiso products. In addition, resources including such as industry-wide environmental product declarations, technical and product bulletins, building code resources, and educational materials, are available at http://polyiso.org, the website of PIMA, the Polyisocyanurate Insulation Manufacturers Association.

Benefits of Polyiso in Below Grade Applications:

  • Eliminates thermal bridging, improving thermal efficiency

  • Resists water absorption

  • Reduces the risk of moisture infiltration

  • Protects the waterproofing or damp-proofing from damage caused by backfill

  • Keeps the wall warm, reducing the potential for condensation on the interior surface of the wall

  • Keeps the wall warm, reducing the impacts of freeze-thaw structural damage

  • Improves the durability of the foundation as it protects against moisture migration

  • Offers consistent thermal resistance by eliminating thermal bridging

  • Durable aluminum facer protects boards from backfill during construction

  • Closed-cell foam

  • Meets ASHRAE 90.1 below-grade water absorption requirements

Click below to read the full article.