The choice of lining material for any
air-distribution system is an important consideration for the specifying
engineer. There are many options available and each material has a potential
impact on project cost and thermal/acoustical performance. While the
traditional lining materials in the industry have been fiberglass-based, there
are other alternatives available today. These new materials have many
advantages from the standpoint of physical properties as well as cost and performance.
In order to successfully promote these new materials, it is helpful to have a
better understanding of current industry standards and how they are applied.
There are several agencies that set
standards for ductwork and equipment-lining materials. They include the
American Society for Testing and Materials International (ASTM), National Fire
Protection Association (NFPA) and Underwriters Laboratories Inc. (UL). While
most of the standards they publish must be purchased and can be costly to acquire,
it is often not necessary to know more than the title of the standard when
determining whether a material is in compliance. Here are some of the most
frequently referenced standards:
- ASTM
C411 - Standard Test Method for Hot-Surface Performance of High-Temperature
Thermal Insulation
- ASTM
C518 - Standard Test Method for Steady-State Thermal Transmission
Properties by Means of Heat Flow-Meter Apparatus
- ASTM
C665 - Standard Specification for Mineral-Fiber Blanket Thermal Insulation
for Light Frame Construction and Manufactured Housing
- ASTM
C739 - Standard Specification for Cellulosic Fiber Loose-Fill Insulation
- ASTM
C1071 - Standard Specification for Fibrous Glass Duct-Lining Insulation
(Thermal and Sound-Absorbing Material)
- ASTM
C1104 - Standard Test Method for Determining the Water Vapor Sorption of
Unfaced Mineral-Fiber Insulation
- ASTM
C1338 - Standard Test Method for Determining Fungi Resistance of
Insulation Materials and Facings
- ASTM
E84 - Standard Test Method for Surface-Burning Characteristics of Building
Materials
- ASTM
E96 - Standard Test Methods for Water-Vapor Transmission of Materials
- ASTM
G21 - Standard Practice for Determining Resistance of Synthetic Polymeric
Materials to Fungi
- ASTM
G22 - Standard Practice for Determining Resistance of Plastics to Bacteria
- NFPA
90A - Standard for the Installation of Air-Conditioning and Ventilation
Systems
- NFPA
90B - Standard for the Installation of Warm Air Heating and
Air-Conditioning Systems
- NFPA
225 - Standard Method of Test of Surface-Burning Characteristics of
Building Materials
- UL
181 - Standard for Factory-Made Air Ducts and Air Connectors
- UL
723 – Standard for Test for Surface-Burning Characteristics of Building
Materials
These standards are commonly referenced in equipment
specifications, and most of them only cause confusion. The first thing to note
is that each of these standards is either a test method or specification. Test
methods define a procedure for measuring a physical property associated with a
material. These procedures are often material specific. Specifications (often
simply entitled “Standard”) generally reference several acceptable test methods
and set maximum or minimum limitations on the result of a test for compliance.
In order to determine compliance with a
specification requirement, it is important to note whether the referenced
standard is an actual specification or just a method of test. Since there is no
way to comply with a test standard, the inclusion of test standards in a
specification often causes confusion for vendors. Another common problem
involves specification that describe a specific lining material, but reference
standards that do not apply to that specific material. All of these issues can
be identified and clarified by simply knowing the full titles of the referenced
standards.
In addition to the aforementioned ASTM,
NFPA and UL standards, there are additional industry standards published by the
Air-Conditioning, Heating and Refrigeration Institute (AHRI), American Society
of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE), and U.S.
Green Building Council (USGBC). Traditionally, ASHRAE publishes test standards
for equipment and guidelines for environmental conditions such as ventilation,
indoor-air quality and thermal comfort. AHRI concentrates mainly on equipment ratings
and performance certification. USGBC publishes the Leadership in Energy and
Environmental Design (LEED) standard.
Since most new construction projects
will be designed with a goal toward achieving LEED certification, it is
important to know what the USGBC requirements are for ductwork and equipment
linings. According to the latest LEED 2009 standard, in order to achieve Indoor
Environmental Quality (IEQ) Prerequisite 1, the building design must meet the
minimum requirements of Sections 4 through 7 of ASHRAE Standard 62.1-2007
Ventilation for Acceptable Indoor-Air Quality. Under Section 5 ‘Systems and
Equipment,’ it states that all airstream surfaces (with the exception of sheet
metal surfaces and metal fasteners) shall be determined to be resistant to mold
growth in accordance with a standardized test method such as those found in UL
181 or ASTM C1338. In addition, all airstream surfaces (with the exception of
sheet metal surfaces and metal fasteners) shall be determined to be resistant
to air erosion in accordance with the test method described in UL 181. In other
words, any lining material that can meet the requirements of UL 181 is
acceptable for use in any LEED-certified building.
Here are some typical questions about
liner specifications and standards:
Does that mean I can put exposed
dual-density fiberglass in a LEED Platinum building?
Yes, it does. However, it may not be
the best choice. Many engineers are looking for alternatives to fiberglass
because no one knows how that material may be treated in the future. Today,
there are innovative new lining materials that can provide improved indoor-air
quality with little if any increase in cost.
What kind of ‘new liners’ are you
talking about?
Titus has seized the initiative to
eliminate fiberglass from many of our product lines. We currently
offer our latest EcoShield liner in ½” or 1”-thickness with cloth-facing for
the same price as fiberglass. This material is made from pre-consumer recycled
natural cotton fibers chemically-treated to be fire-retardant and
anti-microbial. The same material is also available with a scrim-reinforced
foil-facing for critical environmental applications for a modest up-charge. We
also offer our FibreFree liner in 3/8” or 1”-thickness. This material is called
engineered polymer foam insulation (EPFI). It contains an anti-microbial agent
throughout to fight mold growth and cannot absorb any moisture, making it ideal
for humid climates and applications wherein moisture can cause problems.
I submitted EcoShield on a project
recently, but was rejected by the engineer because I could not prove that this
material meets ASTM C1071. Why does EcoShield not meet ASTM C1071?
EcoShield technically cannot meet ASTM
C1071 because that standard only applies to fiberglass products. That does not
mean that EcoShield is not suitable as a duct-lining material, because it may
actually outperform fiberglass in the same tests. The engineer’s standard specification
probably only takes into account fiberglass products and does not address the
new liners available today. We suggest providing EcoShield submittal
sheets, explaining the advantages and encouraging him to update his standard
specification to include newer materials. So long as the lining materials meet
UL 181, they should be acceptable.
With a better understanding of the
industry standards, it should be easier to promote new and better lining
materials to the engineering community.
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