Introduction to ASTM E 119

The IBC, IFC, and NFPA require minimum fire-resistance ratings for various building materials, components, and assemblies. These fire-resistance ratings are based on the data and testing provided by ASTM, according to the procedures outlined in ASTM E 119. These codes point the user, by reference, to ASTM E 119,  Typically this reference is preceded by terminology such as, “...tested in accordance with”.

ASTM E 119 is the guiding document for the Standard Test Methods for Fire Tests of Building Construction and Materials. This document provides the fire-test-response criteria and procedures for structural materials used in building construction. The application of the test procedures contained in ASTM E 119 is to “evaluate the duration for which” building construction materials and assemblies can either contain a fire, retain structural integrity or both. The types of assemblies to be tested include, bearing walls and partitions, columns, floors and roofs, beams, and protective membranes. Specific requirements must be met for these building products to produce a successful (passing) result. These requirements are referred to as “conditions of acceptance”. The conditions of acceptance outline what makes a successful test. If these conditions are not met, then the material or assembly being tested will fail.

The fire-resistance of building materials is determined and based on the standard time-temperature curve. In this temperature controlled environment, building materials receive their hourly rating. The standard time-temperature curve looks like this:

The temperature is measured by the use of thermocouples strategically placed across the product or material to be tested. Utilizing the time temperature curve the temperature data produced by the thermocouples are read and recorded every five to ten minutes.

Both sides of the material, exposed and unexposed, are to be monitored by thermocouples. Both, the IBC and the NFPA, have requirements for nonsymmetrical building assemblies and components. Nonsymmetrical assemblies are constructed of different components on each side. Based on the order in which the materials are assembled, a fire will burn differently, or at a different rate, depending on which side the fire is on. The test report for these types of assemblies will indicate the fire-resistance rating for both sides. This is important to note, as some code requirements state that the fire-resistance rating should be based on the shortest test duration.

Building construction materials and assemblies can be subjected to two types of tests, the fire endurance test and the hose stream test. Based on the type of assembly being tested (floor, wall, column, etc.) there may be a requirement for a load to be applied. To successfully pass, the assembly or material must support the load throughout the duration of time that it is exposed to fire.  The hose stream test is conducted to measure the “impact, erosion, and cooling effects” of a hose stream on the heated surface of the test material. The test types and duration required will be based on the conditions of acceptance for the material being tested.

Video of ASTM E 119 test procedure:

Fire Rated Areas in Hangars

Aircraft hangars are those structures, or portions of, that house aircraft for storage or servicing. Construction and fire protection requirements for these structures is outlined in NFPA 409, Standard on Aircraft Hangars. Hangars are unique structures housing high value goods. To prevent fire or minimize fire damage, and ensure the reliability of fire protection systems, proper fire-rated compartmentalization is critical.  

The table below outlines the required fire-rated areas, as required by NFPA 409.

Click to enlarge.

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• Guide to Hangar Classifications
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Protecting Cable Sleeve Penetrations

An often overlooked, but critical component of building and occupant fire safety is fire barriers, and fire-resistance-rated construction. Beyond reasons of code requirements, fire-rated barriers are an essential component of a buildings life safety system.  These barriers work in conjunction with the sprinkler system to ensure that a fire cannot grow beyond the sprinklers capacity, they provide an area of refuge, and they allow time for occupants to egress a structure. To be effective, these fire barriers must be installed in accordance with their listing, and be free of any openings that could allow for the transport of smoke, heat, and fire from one side to the the other.

Throughout the construction process and the building's lifespan it becomes necessary to penetrate these barriers due to installation of building systems and components. In today's ‘connected’ buildings a main source of these penetrations comes from the need for network cabling to support data and communications networks.

Shows Overfilled Sleeves with firestop only installed on the top side of the sleeve.

Model codes have recognized that this will occur, and have included the following code language in their texts:

NFPA 101:8.3.5.1 - “Penetrations for cables...to accommodate...communications systems shall be protected by a fire stop system or device…”

IFC 703.1 - “Openings made therein [in fire-resistance-rated construction] for the passage of pipes...wires...and holes made for any reason shall be protected with approved methods capable of resisting the passage of smoke and fire.”

As cable networks expand, often times firestop materials are removed and not replaced.  As new cable displaces the firestop system, eventually the system is rendered non-code compliant. Fire inspection personnel should be aware of these conditions and ensure that cable sleeves are properly sealed and the fire-resistance-rating of the floor or wall assembly remains intact.

Here is a checklist of items that can be used to measure the reliability of a properly sealed cable sleeve:

• The third-party tested and listed firestop systems will specify the permissible cable load.
• The cable load for standard cable sleeves is calculated.  The calculated cable load is the aggregate cross-sectional area of cables as a percentage of the aggregate cross-sectional area of the sleeve.  What may appear to be a 50% visual fill, might actually be half that when calculated due to interstitial space between grouped cables.
• Sleeves with missing or partially removed firestopping need to be repaired and cable fill percentage for the listed firestop system should be verified to ensure system remains compliant.
• Firestop systems are mostly installed symmetrically on both sides of the wall or on top side of the floor.  However, listed firestop systems will provide greater detail.
• Firestop materials are often red, but do not necessarily have to be.  There are no code related requirements that dictate color.
• Listed and labeled purpose-made devices with integrated firestopping systems are available to replace traditional cable sleeves or to retrofit existing sleeves.

With the myriad of items that a fire inspector is responsible for looking at, this can prove to be one of the most critical. Having a clear understanding of fire-resistance-rated construction, fire stopping materials, and listed systems and components, can provide a more clear perspective on what to look for during inspection.  

Additional Resources

• International Firestop Council
• QA Inspections for Firestopping
• Listed firestop systems
• Retrofit solution for existing installations

Download the "Firestopping Considerations for Cable Sleeve Penetrations" discussion guide and checklist.