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37-065 (15) 37.. Ogg. Coldham Architects, LLC Tel:413.544.3616 Fax: 6802 t 155 Pine St. Amherst, MA 01002 www.ColdhamArchitects.com MEMO To: Mr. Tony Patillo Tel: 587-1240 Building Inspector Fax: 587-1272 City of Northampton Town Hall,Northampton, MA 01060 r ^ From: Thomas RC Hartman,AIA Cc: Steve Ferrari, Kohl Construction Date: 13 Feb 2006 Project 02-03 RHC Subject: Unvented roofs and vapor barriers Total pages: I Mr. Patillo, Per our discussion last week regarding the potential use of cellulose insulation in an unvented roof assembly, please find the attached 7 documents that reference the evolving perspectives of venting roofs and use of vapor retarders in association with the current code. The purpose of me writing is to determine whether two things might change from the permit drawings filed for the Common House at Rocky Hill Cohousing. 1. Delete venting in the roof assembly for a completely filled cellulose cavity at 3.5 p.c.f. (2x12 rafter @ 16" o:,) 2. Delete the poly vapor retarder at the walls and ceilings. In consideration of these deletions, please note that our firm can assure an air barrier that is between 1-1.25 square inches per 100 sf of building envelope. This is accomplished by performing a blower door test once the insulation is complete and looking for air leakage with a smoke pencil. To evaluate the performance of cellulose alone as an air barrier, we will be performing a test on the last housing unit to be insulated(Unit 25) within the next two weeks to further inform the decisions at the Common House. There will be three tests and I will forward the results of the first two when available: a. with cellulose installed with netting only b. with poly installed and taped over netted cellulose c. after drywall and trim installed(typical Energy Star test) Page 1 of 2 -41 .. ^ eir C `` MEMO Kohl Construction is proceeding on the basis that the roof is vented and the poly vapor retarder will be installed per permit drawings unless directed otherwise. The schedule appears that a decision from me will be required by the end of this month. I will contact you shortly to discuss . Since ay, . j • iIt • ••- asR Haitm/ . , M• Enclosures: o Letter to Tom Riley from National Fiber (NF)- Dec 9, 2005 o Letter from NF-re: vapor transmission o Letter re: Vapor retarder from Mark Kelley, PE- Feb 28, 2005 o Letter from NF- re: unvented cathedral ceilings o Paper from NF-re Fire Blocking o Paper from NF- re Mosture management o Paper from Building Science Corporation- re Roof Design Coldham Architects,LLC Page 2 oft • NF NATIONAL FIBER A DIVISION OF MACGREGOR BAY CORPORATION December 9, 2005 Dear Tom Riley, National Fiber has been producing cellulose insulation in our Belchertown, MA manufacturing facility since 1978 and distributing it throughout the Northeast. Research in the areas of building science continues to expand our understanding of building systems and is challenging many of our long held beliefs and building code requirements. National Fiber is a member of the Building Enclosure Council of the Boston Society of Architects and actively participates in building science events nationwide. National Fiber is asking for a statewide code exemption under the Alternate Materials and Systems provision of the code for the use of our cellulose insulation in the following residential and commercial applications: 1. In building assemblies (i.e. walls, ceilings, etc.), preempting the requirement for code mandated vapor barriers. 2. Constructing non-vented cathedral (i.e. sloped) ceilings and flat roof assemblies. 3. For use as a fire blocking material when installed at depths of 14.5 inches or greater. This request is based upon both building science and a historical use of cellulose insulation in these applications nationwide. Our position is that when cellulose insulation is used in the three applications outlined above, it is not only equivalent to conventional practices meeting current code requirements in the State of Massachusetts, but it also exceeds them in terms of building durability, safety, and performance; and it certainly meets the standard for the Alternate Materials and Systems provision. We have been successful in many areas of the Northeast in convincing local code officials that the building science and testing presented below supports our position, resulting in thousands of successful installations. Unfortunately, this town by town approach has been very time consuming for National Fiber and local code enforcement personnel; therefore, we request a statewide approval for use of our cellulose insulation without vapor barriers, in un-vented roof assemblies, and as a fire block in the State of Massachusetts. Our Technical Manager, Bill Hulstrunk, is available to meet with your technical group at its convenience to answer any questions or to provide additional information pertaining to this request. He can be reached on his cell phone at(413) 688-6133 or by email at whulstrunk@tds.net . Thank you for your consideration of our request. Sincerely, - 146/1_ Chris Hoch President 50 DEPOT STREET, BEICHERTOWN, MA 01007-9619 . 413-283-8747 . FAR: 413-283-2462 E-Mai ADDRESS: general®natlfiber com WEB PAGE: www.natIfiber com NF NATIONAL FIBER A DIVISION OF MACGREGOR BAY CORPORATION To whom it may concern: This letter addresses vapor transmission through our Cel-Pak and Nu-Wool cellulose insulations. Moisture moves by two transport mechanisms, air movement and by diffusion. Of these, air movement is the most significant accounting for over 98% of the total and is the primary cause for moisture related building failures. When cellulose insulation is blown In or sprayed in above 3.2 Ibs/cuft, the density of the material will block air movement generated by wind, stack effect and mechanical imbalances within the building. By blocking air movement we will reduce moisture movement to inconsequential levels in building assemblies. Any remaining moisture moving by diffusion will be further blocked by primers of paints used on the interior surfaces. In our Northeast climate, a vapor barrier is not only unnecessary but can be potentially harmful especially during the summer months in air conditioned buildings when warm moist air passes through wall assemblies and condenses on the outside of the cool poly vapor barrier. The hygroscopic nature of our cellulose insulation allows it to manage and wick moisture from areas of greater to less concentrations as long as the path is not blocked with a vapor barrier. During most of the year in the Northeast a vapor permeable wall will tend to dry to the outside, while in the summer, this same wall will tend to dry to the inside. Our borate based NuWool cellulose contains an EPA fungicide which resists the growth of mold, even when exposed to conditions favorable to mold growth. Tens of thousands of homes weatherized with cellulose insulation since the 1970's, with no vapor barriers and no evidence of mold, are a testament to this claim. Sophisticated moisture modeling of cellulose insulated building assemblies without a vapor barrier show faster drying and lower overall moisture levels over identical assemblies with vapor bafflers installed. Please see the attached report from Mark E. Kelley III, PE. In summary, we do not recommend the use of vapor bafflers with our product except in circumstances of exceptionally high moisture levels i.e. pool facilities, and warrantee our cellulose for the life of the building when installed by a certified National Fiber contractor. If you have any questions or would like to discuss this further, please call me at (802) 485-5735 or by email at whulstrunkatds.net. Sincerely, Bill Hulstrunk Technical Manager for National Fiber 50 DEPOT STREET, BELCHERTOWN, MA 01007-9619 . 413-283-8747 . Fsa: 413-283-2462 E-MAL ADDRESS: generalenatlfber.com WEB PAGE: w-.w.natlfibercom BUILDING SCIENCE Mark E. Kelley III, PE PH 978 456-6950 FX 978 456-8080 85 Depot Rd,Harvard,MA 01451 February 28,2005 To whom it may concern: Dear Sir or Madam, In regard to the 2X6 wood-framed cellulose insulated wall system, we have investigated options for moisture control and air infiltration control. Experience in the field, research and moisture modeling all are in agreement that the lowest potential for moisture accumulation in a wall of this type occurs when no vapor retarder is used on the inside of the insulated wall. The Oak Ridge National Laboratory has produced a sophisticated moisture modeling program called WUFI. This program is a far better analysis of moisture potential than the older dew point approach, and can give detailed moisture profiles for wall systems over time. Below are two graphs showing modeled moisture content of walls with and without vapor retarder. The systems were modeled for 1 % years starling in January, with typal weather (temperature, rain humidity,etc.)and interior moisture and temperature conditions. As can be seen, both assemblies will dry out over time, but the system without vapor retarder dries more quickly and thoroughly than the one with the vapor retarder. Two by six wall construction with exterior air barrier,cellulose insulation and 6 mil polyethylene vapor retarder. 40 x 30 c 20 E 10 0 0 0 96 192 288 384 480 576 Time[d[ • Page 2 February 28,2005 Two by six wall construction with exterior air baffler,cellulose insulation and no vapor retarder. 40 - C C 24 m Ts 10 0 0 96 192 288 384 480 576 Time{d] Our investigations and the recommendations of the cellulose industry agree that the wall system with the lowest moisture accumulation potential is one with no interior vapor retarder. Further, the draft International Energy Conservation Code (IECC), does not require a vapor retarder in walls for Massachusetts because of budding science considerations. In summary, we believe that the science and experience with these wall systems strongly indicates that the best way to construct the wall is to omit the interior oda retarder. I would like to emphasize that builders are trying to build the most efficient, healthy and durable houses possible. It is true that the omission of the vapor retarder will save a small amount of money, but the reasons for doing so have only to do with doing it right, not cost savings. The builder is primarily interested in producing the twst wall system possiNe, and it is our belief that the best cellulose insulated wall will have no vapor retarder. As a professional engineer, I attest to the omission of the vapor retarder in this case as the best approach for building performance and durability. On this basis we wish to apply for an exception to Section 780 CMR 34.2.1 of the Massachusetts State Building Code to allow this improved mnstnrction. 0011 sr ra4„ Since l74/) t 1 J., AFU Cr slit? fR Mark E.Kelley Ill, PE President <" Budding Science Engineering NF NATIONAL FIBER A DIVISION OF MACGREGOR BAY CORPORATION To whom it may concern: Unvented cathedral ceilings have been used successfully for many years across the United States and Canada. When cellulose insulation is installed at high densities(3.5 lbsicuft), it provides a barrier to the warm moist air from the living space below and eliminates the need for attic ventilation in cathedral ceilings. The lower density of fiberglass insulation does not provide the same barrier to warm moist air,and therefore requires venting to remove the moisture and hot air from a fiberglass insulated cathedral ceiling. o Oak Ridge National Laboratory states in their publication Moisture Control Handbook, under the heading "Should cathedral ceilings be ventilated?"they recommended"Not if that space is tightly packed with insulation," o Researchers at the University of Illinois studied the effects of attic venting and heat transfer and concluded "...an analysis of the data reveals that the addition of 2-inch thick insulation is considerably more effective at reducing ceiling heat gains that the maximum ventilation rate When 3$/8 inches is added thee'ec.ts of ventilation is almost insignificant° o At the ASHRAE/DQE Thermal Envelopes Conference in Clearwater, Florida, an international group of building scientists and contractors concluded that un- vented cathedral ceilings provide better thermal performance and better moisture protection than conventionally vented cathedral ceilings. o Roofing Siding & Insulation magazine advocated unvented cathedral ceilings in their magazine"If properly constructed and sealed to prevent air leakage° o Princeton University found that cellulose insulation has the lowest air infiltration rates of any commonly used home insulation. One of the concerns raised is the shingle warranty. We are not aware of any warranty that is invalid because the unvented cathedral is packed with insulation. Studies have proven that excess heat of a roof is a function of roof color and not ventilation. National Fiber warranties its cellulose insulation in unvented cathedral roof assemblies with rafter depths of 2 x 10 or greater and having a minimum installed density of 3.5 lbs/cuft when installed by a certified National Fiber contractor. We recognize that interior moisture conditions can also have a detrimental effect on any insulation system. This warranty does not extend to homes that have an unusually high interior relative humidity levels, such as indoor heated pool enclosures. If you have any questions or would like to discuss this further, please call me at(802) 485-5735 or by email at whulstrunkCrD_tds net. Sincerely, 6;2i c9~ Bill Huistrunk Technical Manager for National Fiber SO Duce Sn., ,(, 8i i,n,e,omv. MA 01007-9619 * 413-283-8747 - FAA: 413-283-2462 E-Mn, An4 general4➢rwilfiber corn. Woa ova-vonv,natIfibe4 corn National Fiber's Cellulose Insulation as a Fire Block Fire blocking is designed to stop the passage of fire and hot gases through walls, floors and concealed spaces. There are many materials and methods, including National Fibers cellulose insulation that can be used effectively as a fire blocking material. Historical Perspective The use of fire stopping provisions in the U.S. building codes dates back to the mid 1980's. The earlier fire stopping language was adapted from provisions for non-combustible materials,tested in accordance with ASTM E 136. This methodology was being used for specifying materials suitable for use around chimneys and metal flue pipes, which can become quite hot. After implementing the non-combustible material language, code and building officials began to recognize that this requirement"missed the mark", since neither fire retardant treated wood fire blocking nor 5/8"sheetrock that had been demonstrated to perform in fire rated assemblies would pass the narrowly defined ASTM E 136 test. In 2000, both the IBC and IRC (in Section R602.8)eliminated the"non-combustible" material requirement for fire blocks and adopted the language"approved material to resist the free passage of flame and the products of combustion", which more precisely reflected the intent of the code. ASTM E 136 Test The ASTM E 136 test exposes a sample of material on a tray to 1382°F in a vertical tube furnace for a minimum of five minutes. The material fails the test if: 1. The temperature inside the material rises above 1436°F. 2. The material loses up to 50%of its mass and any flaming is observed after the first 30 seconds of the test. 3. The material loses over 50%of its mass and any flaming is observed. Unfaced fiberglass insulation passes the ASTM E 136 test, but at temperatures above 1100°F begins to soften and melt. Since the material is weighed on the tray, even though it may have melted, it would still pass the test. Unfortunately, when glass fiber is subjected to structural fires, this melting allows flames to spread very quickly along building cavities. Noncombustible material ratings do not necessary equate with increased fire safety or performance. Cellulose insulation on the other hand, like all wood based products, does not meet the ASTM E136 standard due to surface flaming. Ironically, it is the surface flaming that allows the boric acid fire retardant to produce a protective layer of char on the surface of the cellulose insulation, which impedes further flame spread and damage to the material. Also, cellulose insulation does not melt, providing an effective barrier against the spread of flames and hot combustion gases. Fire Resistant Properties National Fiber's borate treated cellulose insulation achieves the highest and most fire resistant material rating of Class A/Class 1 under ASTM E 84 and passes the strict Federal 16 CFR Part 1209, ASTM C739 and ASTM E 970 requirements, having a flame spread index of 20 and a smoke developed of 0. ASTM E-119 Test The ASTM E 119 test exposes various building assemblies to an open flame. Temperatures are recorded on both sides of the assembly with temperatures as high as 2350°F on the flame side. The test continues until the assembly fails or collapses and the recorded time is the fire rating of the assembly. Adding cellulose insulation to wood frame walls increases their fire resistance rating by 15 minutes, Our cellulose is ASTM E 119 tested and UL approved for use in a variety of wall and floor/ceiling fire rated assemblies. For example, Southwest Research Institute Project #01-5920-611 tested and approved a one hour fire rated load bearing wall assembly, consisting of a single layer of Y"sheetrock on both sides of a 2 x 4 stud wall filled with cellulose insulation. Rock wool,fiberglass or foam insulation can not be substituted in this type of fire rated wail assembly since they do not offer the same level of fire protection. In 1994 the Research Council of Canada(NRCC) reported that fiberglass decreased the fire resistance of insulated walls while cellulose produced a 22%to 55%increase in fire resistance. In 1995 the NRCC tested floor-ceiling assemblies and found that cellulose increased the fire resistance more than twice that of fiberglass. The report compared rock wool and cellulose fiber insulations and found that the cellulose increased the fire resistance over rock wool by 40%. Current Building Codes National Fiber's cellulose insulation has been approved as fire blocking material under Section 708.2.1, Item 1, of the UBC, and Section 716.2.1 of the IBC. Cellulose is permitted as an alternate to the fire blocking in Section R602.8, Item 1, of the IRC, as validated by Omega Point Laboratories Report for Project No. 16094-11638. The International Building Code(IBC)2000&2001 Amendments also allow electrical outlet boxes to be installed on opposite sides of a one hour firewall if they are offset by 3.5 inches of cellulose insulation. This offers greater design flexibility over fiberglass which requires a minimum of 24 inches separation between outlets. Application of Cellulose Fire Blocking When installed in a dry or spray application to a depth of 14.5 Inches, cellulose outperforms conventional wood fire blocking in the Omega Point fire blocking tests, Project No. 16094-11638. Cellulose insulation may be used in new or existing wood or steel stud walls and partitions of combustible construction with stud spacing up to 24 inches on center. In uninsulated walls or partitions, cellulose is sprayed or dry blown,filling the stud cavity completely. Cellulose fire blocking can also be installed in walls and partitions with existing insulation, by cutting and pushibg away the existing insulation to form a minimum 14.5 inch deep cavity. Cellulose insulation is sprayed or dry blown into this cavity,filling the full 14.5 inches or greater depth and contacting all surfaces. Conclusion Numerous US and Canadian studies, including full size burn tests, have confirmed cellulose insulation's superior performance in terms of fire resistance. The permanently impregnated borate based tire retardants and high installed densities allow cellulose insulation to retard the propagation of fire and hot gases by resisting flame spread and remaining in place much more effectively than other types of insulation and non fire retardant treated building materials. Therefore, we are recommending that National Fiber's cellulose insulation, when installed at a depth of 14.5 inches or greater, be allowed as an alternative fire blocking material in the state of Massachusetts. How Cellulose Insulation Manages Moisture without Vapor Barriers and Performs in Non-vented Cathedral and Flat Roof Assemblies Historical Perspective Cellulose has been used as a building insulation for a long time. Thomas Jefferson used an early form of cellulose in his Montecello home more than 200 years ago. The modern form of cellulose has been in production since the 1920's, coming into general use after World War 2, and was used extensively in electrically heated homes during the 1950's and 1960's. After the energy crisis of the early 1970's, over a million homes were either retrofitted or constructed using cellulose insulation, most without vapor barriers or venting in cathedral ceiling or flat roof applications. The cellulose industry continues to evolve with new fiberization processing technology. Improved application techniques, including dry dense pack and high pressure low moisture spray, assures consistency and exceptional performance. Over the years, thousands of cellulose insulated homes have been renovated or expanded, giving us an opportunity to see how the insulation and the building structure have performed over time. National Fiber has never seen, nor are we aware of, a single documented instance where there has been either a failure or degradation of the building structure due to vapor diffusion through our cellulose insulation. This should be contrasted against the widespread deterioration and instances of mold found in air permeable insulation systems (i.e. fiberglass and rock wool) from gaps in the air barrier, typically found around outlets, recessed lights or other penetrations. Properties of Cellulose Cellulose insulation is made from re-cycled cellulosic newprint, with boric acid or a boric acid - ammonium sulfate blend added to suppress combustion. The ability of cellulose insulation to manage moisture without a vapor barrier or venting is a function of many aspects including the cellulose fibers themselves, the fire retardant chemicals, and the installation methods. The beneficial moisture management properties that cellulose fibers impart upon the cellulose insulation include the effects of hysteresis, the hygroscopic nature of the material, and its storage and buffering properties. Hysteresis allows the cellulose fibers in the insulation to remain at a lower moisture content than the surrounding air. This allows the cellulose insulation to remain at 7% moisture content when exposed to a constant indoor relative humidity of 50% without a vapor barrier. In order for the cellulose fibers to reach the fiber saturation point (the point at which liquid water becomes available) it would require an exposure to a constant indoor humidity level of well over 80%. (see Figure 1) out of the top of a vented roof will exceed the temperatures of an equivalent unvented roof assembly. If heat from solar gain were a factor in shingle life, then shingles over vented roofs would fail more quickly at the top of the roof than the bottom, which is not the case. Research has shown that shingle color, not ventilation, has the greatest impact on roof temperatures. Research on Non-Vented Ceilings o Oak Ridge National Laboratory, in their publication Moisture Control Handbook, answers the question, "Should cathedral ceilings be ventilated?," by recommending, "Not if that space is tightly packed with insulation." o Roofing Siding & Insulation magazine advocated unvented cathedral ceilings in their magazine, "if properly constructed and sealed to prevent air leakage." o At the ASHRAE/DOE Thermal Envelopes Conference in Clearwater, Florida, an international group of building scientists and contractors concluded that un-vented cathedral ceilings provide better thermal performance and better moisture protection than conventionally vented cathedral ceilings. o Researchers at the University of Illinois studied the effects of attic venting and heat transfer and concluded "...an analysis of the data reveals that the addition of 2-inch thick insulation is considerably more effective at reducing ceiling heat gains that the maximum ventilation rate. When 3 5/8 inches is added the effects of ventilation is almost insignificant." o Princeton University found that cellulose insulation has one of the lowest air infiltration rates of any commonly used home insulation. Conclusion The ability of cellulose to excel in a wide range of moisture conditions comes from a variety of attributes, including its physical properties, chemical components and installation techniques. These attributes allow cellulose to provide superior insulation performance in moisture conditions that would cause other insulation products to fail. The vapor retarder and cathedral ceiling venting provisions of the code are designed to protect buildings from an accumulation of moisture which would accelerate the deterioration of the structure. Cellulose insulation accomplishes this task without the need of a separate vapor retarder or venting in cathedral ceiling or flat roof applications, while at the same time providing superior thermal, fire and sound performance. Therefore, National Fiber is suggesting that you take under consideration a statewide code exemption under the Alternate Materials and Systems provision of the Massachusetts building code for the use of our cellulose insulation in building assemblies without a vapor barrier, and in non vented cathedral and flat roof assemblies. responsible for the majority of the building failures we see with air permeable fibrous insulation materials. Diffusion on the other hand transports moisture at a much slower rate, and is slowed further by paints and other surface finishes. Current Code Provisions More recent versions of the building codes, including the 1999 National Building Code (NBC), Chapter 13, Section 7.23.3.1; 2000 International Building Code (IBC), Section 1403,3; and International Energy Conservation Code (IECC), Section 502.1.1, allow the use of cellulose insulation as an alternate/ exemption to the requirements for the installation of a separate vapor barrier. Vapor Barrier Research This is what some of the leading building scientists and researchers are saying on the subject of omitting vapor retarders when using cellulose insulation: o Research by Canadian Researchers, reported in "A side-by-side field test in Calgary, Alberta, sponsored by the Canadian Mortgage Housing Corporation, found that 6-inch walls insulated with damp cellulose performed just as well without a vapor retarder as identical walls with a polyethylene vapor retarder. Five months after construction, the moisture content in both wall sections was "nearly identical." o Mark Kelley, PE and President of Building Science Engineering modeled cellulose insulated wall assemblies with and without a poly vapor barrier using a moisture modeling program called WUFI and found that "...the system without vapor retarder dries more quickly and thoroughly than the one with the vapor retarder." He concluded that "...the best cellulose insulated wall will have no vapor barrier." Many code officials and building scientists have questioned the need for a poly vapor retarders in climates with both heating and cooling loads: o Building Scientist Joe Lstiburek in his Moisture Control Handbook Errata stated "Polyethylene should not be installed on the interior of any assembly —with the exception of above grade walls and ceilings in locations with 8,000 heating degree days or greater." The heating degree days for the state of Massachusetts is below 8000 in all areas. This recommendation is based upon the fact that during the summer, warm moist air infiltrates building assemblies, it condenses on cool surface of the poly in air conditioned buildings, and this leads to mold, rot and structural degradation. o Canadian research scientist John Staube noted "People install vapor retarders to control outward diffusion, but in modern buildings a bigger problem is inward vapor drives during warm weather." He continued "Poly vapor retarders are unnecessary, even in most cold climates. But they are a serious problem in mixed climates where the presence of poly practically eliminates the ability of a wall to dry inward," o The USDOE Building America "Vapor Barrier Journal, Paper 5.C.2.1," lists, under the following headings: o "The following things are discouraged: The installation of vapor barriers such as polyethylene vapor barriers, foil faced batt insulation and reflective radiant barrier foil insulation on the interior of air-conditioned assemblies? o "The following things are encouraged: The construction of assemblies that are able to dry by diffusion to at least one side and in many cases both sides." Other research has found air and water leakage to be the most significant factors involving moisture in buildings, The high installed density of the cellulose insulation blocks air leakage, while poly vapor barriers slow the drying of building assemblies should they get wet due to water intrusion. o Three extensive field studies conducted by George Tsongas, professor of mechanical engineering at Portland State University, found virtually no relationship between vapor retarder presence and moisture content in walls. A fourth study did find a correlation between air leakage sites in walls and moisture problems. o Anton TenWolde of the USDA Forest products laboratory states, "Diffusion is hardly ever what is going on when you have moisture problems,".... "This research has led to a disproportionate emphasis on the water vapor permeability of various materials, allowing a minor problem to dwarf causes that are more significant." According to TenWolde, "diffusion runs a distant third to both water leakage and water vapor carried by air movement as the bigger culprits behind the majority of moisture problems in buildings." o The United States Department of Energy (USDOE) "Wall Insulation" technology fact sheet states, under the heading of Moisture Control, "It is a myth that installing a vapor barrier is the most important step for controlling moisture in walls. Vapor barriers only retard moisture due to diffusion, while most moisture enters walls either though fluid capillary action or as water vapor through air leaks" Non-Vented Cathedral and Flat Ceilings The same air blocking and moisture management properties that allow cellulose to perform well without a vapor barrier, also allow it to work well in non vented cathedral and flat ceilings. National Fiber warranties its cellulose insulation in unvented cathedral roof assemblies with rafter depths of 2 x 10 or greater and having a minimum installed density of 33 lbs/cuft when installed by a certified National Fiber contractor. We recognize that interior moisture conditions can also have a detrimental effect on any insulation system. We do not recommend this treatment in buildings that have an unusually high interior relative humidity levels, such as indoor heated pool enclosures. Earlier concerns with elevated roof temperature and reduced shingle life have been investigated and found to be insignificant. We are not aware of any shingle warranty that is invalid because the unvented cathedral is packed with cellulose insulation. A vented roof system can be thought of as a giant solar collector, where cooler air is drawn into the bottom, continually heated as it moves up the roof system before being exhausted out the ridge of gable end vents. On a sunny day, the heat exiting out of the top of a vented roof will exceed the temperatures of an equivalent unvented roof assembly. if heat from solar gain were a factor in shingle life, then shingles over vented roofs would fail more quickly at the top of the roof than the bottom, which is not the case. Research has shown that shingle color, not ventilation, has the greatest impact on roof temperatures. Research on Non-Vented Ceilings o Oak Ridge National Laboratory, in their publication Moisture Control Handbook, answers the question, "Should cathedral ceilings be ventilated?," by recommending, "Not if that space is tightly packed with insulation." o Roofing Siding & Insulation magazine advocated unvented cathedral ceilings in their magazine, If properly constructed and sealed to prevent air leakage." o At the ASHRAEDOE Thermal Envelopes Conference in Clearwater, Florida, an international group of building scientists and contractors concluded that un-vented cathedral ceilings provide better thermal performance and better moisture protection than conventionally vented cathedral ceilings. o Researchers at the University of Illinois studied the effects of attic venting and heat transfer and concluded"...an analysis of the data reveals that the addition of 2-inch thick insulation is considerably more effective at reducing ceiling heat gains that the maximum ventilation rate. When 3 518 inches is added the effects of ventilation is almost insignificant." o Princeton University found that cellulose insulation has one of the lowest air infiltration rates of any commonly used home insulation. Conclusion The ability of cellulose to excel in a wide range of moisture conditions comes from a variety of attributes, including its physical properties, chemical components and installation techniques. These attributes allow cellulose to provide superior insulation performance in moisture conditions that would cause other insulation products to fail. The vapor retarder and cathedral ceiling venting provisions of the code are designed to protect buildings from an accumulation of moisture which would accelerate the deterioration of the structure. Cellulose insulation accomplishes this task without the need of a separate vapor retarder or venting in cathedral ceiling or flat roof applications, while at the same time providing superior thermal, fire and sound performance. Therefore, National Fiber is suggesting that you take under consideration a statewide code exemption under the Alternate Materials and Systems provision of the Massachusetts building code for the use of our cellulose insulation in building assemblies without a vapor barrier, and in non vented cathedral and flat roof assemblies. a o "The following things are discouraged: The installation of vapor barriers such as polyethylene vapor barriers, foil faced batt insulation and reflective radiant barrier foil insulation on the interior of air-conditioned assemblies." o 'The following things are encouraged: The construction of assemblies that are able to dry by diffusion to at least one side and in many cases both sides." Other research has found air and water leakage to be the most significant factors involving moisture in buildings. The high installed density of the cellulose insulation blocks air leakage, while poly vapor barriers slow the drying of building assemblies should they get wet due to water intrusion. o Three extensive field studies conducted by George Tsongas, professor of mechanical engineering at Portland State University, found virtually no relationship between vapor retarder presence and moisture content in walls. A fourth study did find a correlation between air leakage sites in walls and moisture problems. o Anton TenWolde of the USDA Forest products laboratory states, "Diffusion is hardly ever what is going on when you have moisture problems,".... "This research has led to a disproportionate emphasis on the water vapor permeability of various materials, allowing a minor problem to dwarf causes that are more significant." According to TenWolde, "diffusion runs a distant third to both water leakage and water vapor carried by air movement as the bigger culprits behind the majority of moisture problems in buildings." o The United States Department of Energy (USDOE) "Wall Insulation" technology fact sheet states, under the heading of Moisture Control, "It is a myth that installing a vapor barrier is the most important step for controlling moisture in walls. Vapor barriers only retard moisture due to diffusion, while most moisture enters walls either though fluid capillary action or as water vapor through air leaks." Non-Vented Cathedral and Flat Ceilings The same air blocking and moisture management properties that allow cellulose to perform well without a vapor barrier, also allow it to work well in non vented cathedral and flat ceilings. National Fiber warranties its cellulose insulation in unvented cathedral roof assemblies with rafter depths of 2 x 10 or greater and having a minimum installed density of 3.5 lbs/cuft when installed by a certified National Fiber contractor. We recognize that interior moisture conditions can also have a detrimental effect on any insulation system. We do not recommend this treatment in buildings that have an unusually high interior relative humidity levels, such as indoor heated pool enclosures. Earlier concerns with elevated roof temperature and reduced shingle life have been investigated and found to be insignificant. We are not aware of any shingle warranty that is invalid because the unvented cathedral is packed with cellulose insulation, A vented roof system can be thought of as a giant solar collector, where cooler air is drawn into the bottom, continually heated as it moves up the roof system before being exhausted out the ridge of gable end vents. On a sunny day, the heat exiting ®2084 Building Science Corporation 1 Roof Design Hoofs can be designed and constructed to be either vented the roof deck and the top of the cavity insulation.This not or unvented in any hygro-thermal zone, a code requirement but ought to be(only 1-inch is typically In cold climates,the primary purpose of attic ventilation is specified). to maintain a cold roof temperature to avoid ice dams cre- In addition to an air barrier at the ceiling line,a Class II va- ated by melting snow,and to vent moisture that moves pot retarder should be installed in Climate Zone 6 and Cli- from the conditioned space to the attic.Melted snow,in mate Zone 7.A Class III vapor retarder is acceptable in Cli- this case,is caused by heat loss from the conditioned space. mate Zone 5. In hot climates,the primary purpose of attic ventilation is Class I vapor retarders(i.e.vapor barriers)can be installed to expel solar heated hot air from the attic to lessen the in vented roof assemblies in Climate Zone 6 and Climate building cooling load. Zone 7 but should be avoided in Climate Zone 5 as top side condensation may occur in the summer months during air The amount of roof cavity ventilation is specified by nu- merous ratios of free vent area to insulated ceiling area conditioning periods. ranging from 1:150 to 1:600 depending on which building No interior roof assembly-side vapor control is required or code is consulted,the 1:300 ratio being the most common. recommended in climate zones other than cold or very Control of ice dams,moisture accumulation and heat gain cold. can also be facilitated by unvented roof design. Roof"sWalon Co n eron s ridge—. Oeapproach Insulation wind lle 2'minimum space In cold climates the main strategy that should be utilized water protection venin when designing roofs to be free from moisture problems membrane 4:-.0"" 'III e and ice dams along with control of heat gain or heat loss I I �I��I!'!'!'!'�,'�'�' regardless of ventilation approach is the elimination of air _/'I'�II'II�11� �1, ' movement,particularly exfiltrating air.This can be accord- a: _ plished by the installation of an air barrier system or by the �I— =04i• Gypsum board air arrier control of the air pressure difference across the roof sys- d►� tem. soffit vent '� Consider increasing depth or Air barriers stems are typically the most common a - I �� 'russes or ov9rs'i:edeeper ong Y YP Y P Vinyl nvmr I �� trusses 9B11 proach,however,air pressure control approaches are be- aluminum siding I Caulking sealant coming more common especially in cases involving reme- Rigid insulation i � Gypsum board Flints) work on existing structures. (taped or sealed �nts) a Vapor diffusion should be considered as a secondary mois- eolulossee an owidenl:ayn' ture transport mechanism when designing and building cellulose loam roofs.Specific vapor retarders are often unnecessary if ap- propriate air movement control is provided or if control of Figure 1 condensing surface temperatures is provided. hell Roof Assembly •Roof insulation thermal resistance(depth)at truss heel(roof perimeter)should be equal or greater to thermal resistance of Vented Roof Design exterior wall •1.300 roof ventilation ratio recommended Vented roofs should not communicate with the conditioned space—they are coupled to the exterior.Therefore,an air barrier at the ceiling line should be present to isolate the at- Ihallatod Raaf Design tic space from the conditioned space.No services such as HVAC distribution ducts,air handlers,plumbing or fire Unvented roof design falls into two categories: systems sprinkler systems should be located external to the air bar- where condensing surface temperatures are controlled and riot(Figure I). systems where condensing surface temperatures are not controlled.The two categories essentially are the demarca- The recommended ventilation ratio to provide in vented tion between regions where cold weather conditions occur roof assemblies when an air barrier is present,is the 1:300 with sufficient frequency and intensity that sufficient mois- ratio(as specified by most codes). ture accumulation from interior sources can occur on an In vented cathedral ceiling assemblies a minimum 2-inch uninsulated roof deck to risk mold,corrosion and decay problems. clear airspace is recommended between the underside of 2D114 Building Science Corporation 2 The key is to keep the roof deck—the principle condens- construction has sufficient hygric buffer capacity to absorb, ing surface in roof assemblies—sufficiently warm redistribute and re-release significant quantities of con- throughoitt the year.This can be accomplished either be- densed moisture should intermittent condensation occur cause of the local climate or as a result of design princi- during cold nights when the sheathing temperature occa- pally through the use of rigid insulation installed above the sionally dips below 45 degrees F.The average monthly roof deck or air-impermeable spray foam insulation in- conditions more accurately reflect moisture content in stalled under the roof deck in direct contact with it. wood-based assemblies. Where rigid insulation is installed above the roof deck,or Asphalt roofing shingles require special attention when in- air-impermeable spray foam insulation is installed under stalled on unvented roof assemblies in hot-humid,mixed- the roof deck condensing surface temperatures are said to humid and marine climates due to inward vapor drive from be controlled. incident solar radiation.A I perm or lower vapor retarder The demarcation is specified as a distinction between rn- (Class 71)as tested by the wet-cup procedure should be in- gions where the monthly average temperature remains stalled under the asphalt roofing shingles to control this in- above 45 degrees F throughout the year and where it drops Ward drive. below 45 degrees F during the year.An additional criteria Wood shingles or shakes,require a minimum%cinch is also necessary-that of keeping interior relative humidi- vented airspace that separates the shingles/shakes and the ties below 45 percent. roofing felt placed over the roof sheathing for similar rea- sons. These criteria were selected for two reasons.First,by keep- ing the roof deck above 45 degrees F,condensation can be The demarcation between regions that require the control minimized or eliminated.Condensation will not occur un- of condensing surface temperatures and regions that do not less the dewpoint temperature of the interior air exceeds 45 can be obtained by using the hygro-thermal zones defied. degrees F and this air contacts the roof deck.This interior tions in this builder's guide.Both hot-humid and hot-dry dewpoint temperature is approximately equal to an interior climate zones meet the 45°F roof deck criteria.However, conditioned space temperature of 70 degrees F at an inle- the high interior humidities found in buildings located in nor relative humidity of 45 percent.These are interior hot-humid zones during the winter months do not always moisture conditions that can easily be avoided with air meet the 45%interior relative humidity criteria.Therefore, change/ventilation or the avoidance of over humidification the only zone that meets hoth of these requirements is the during the coldest month of the year in the climate zones hot-dry hygro-thermal region.Only hot-cry climates do not specified. require the control of condensing surface temperatures.All Second,a monthly average temperature was selected, other regions require some form of control, rather than a design heating temperature,as it is more rep- Control of condensing surface temperatures typically in- resentative of building enclosure performance.Short term, volves the installation of insulating sheathing above the intermittent"spikes"in parameters/environmental loads are roof deck.In residential wood frame construction this in- of interest to structural engineers and in the sizing of equip- volves installing rigid insulation between the roof shingles ment,but not typically relevant to moisture induced date- and the roof plywood or OSB(Figure 2).The installation rioration.Wood-based roof sheathing typical to residential of the rigid insulation elevates the temperature of the roof deck to minimize condensation. smngioz In cold and very cold climates selecting a roof deck con- Rox€ng pyarp perm carerdensing surface temperature criteria of45°Fisvery causer- vapor r Wasted», e N Procedure re rut' omcnnsteal valve.This temperature rature criteria can be reduced to 405F R-o bay rinstalled h , (which corresponds to interior average conditions of 70°F, wire stays or twine ; R3 yd t edrw and horizontal • -Amy% 35%RH)where high interior moisture loads due to spas, , ma out from root sheathing} �. �„inv. indoor swimming pools and excessive humidification are sheathing OMNM 111:411:44.t.:, � PPP not present. R tsheathing � a A 5aai at - /',� •� r Surface is R t a rano Figure 3 and Figure 4 illustrate the differences between the Rigid insulation g/ �► i t f Sheatthlr two fundamental systems.Figure 3 shows the potential for a nee a nd mel l � condensation of an unvented roof assembly in Phoenix, trusses and main = --- name( ..—wtaaed batt mewaz AZ.Phoenix,AZ is located in a hot-dry climate zone.This amminom,jd)g- I d . Gypsum exam with vapor son- roof assembly has no insulating sheathing installed above Rigid insulation(tapee, ► wmiesbm(Mos)paint the roof deck. shiplapped or ssaiadjoints) Figure 4 shows the potential for condensation of an un- Figuro 2 vented roof assembly in Dallas,TX.Dallas,TX is located IffIA( to WM USW Mau Talus in a mixed-humid climate zone.Note that this roof assem- •Rgid insulation installed above roof deCs Sly has rigid insulation installed above the roof deck in or- •Ratio of IR-value between rigid insulation and batt insulation is der to control the condensation potential.The thermal resis- climate-dependent tante of the rigid insulation(thickness)necessary to control 02004 Building Science Corporation 3 condensation depends on the severity of the climate.The Figure 7 shows a roof design that is not as dependent on colder the climate,the greater the resistance of the rigid in- controlling interior moisture levels as the other roof de- sulation required.Note that the thermal resistance of the signs presented.The absence of cavity insulation yields the rigid insulation is based on the ratio of the thermal resis- highest condensing surface temperature of any of the de- tance of the insulation above the roof deck as compared to signs presented.In this particular design,the condensing the thermal resistance of the insulation below the roof surface is the air barrier membrane installed over the wood deck.The key is to elevate the temperature of the condens- decking.With this design interior relative humidities ing surface to 45 degrees F or higher during the coldest should be kept below 60 percent in order to control surface months of the year. mold.In cold and very cold climate zones where there is likely snow accumulation on roof surfaces,there is also the Figure 5 shows the use of rigid insulation in a cathedral ceiling assembly in Washington,DC.A calculation proce- likelihood of ice-damming.In order to control ice-dam- ming,heat flow form the interior to the roof cladding must dure is presented that determines the temperature of thebe condensing surface.This calculation procedure is similar to minimized. In cold climate zones the minimum total R- the one used in Chapter 4 to determine the sheathing tem- 4slue for the entire at ezon roof assembly should be R- vpemmre in wall assemblies. 40.In very cold climate zones this minimum R-value should be increased to R-50. Figure 6 plots the temperature of the condensing surface. The graph shows that condensation within the roof assem- In extreme snow regions it is typical to add a vented air bly will not occur if interior conditions are maintained at space between the roof cladding(shingles)and the rigid in- 45 percent relative humidity or less at 70 degrees F during sulation in Figure 7 to flush heat away trapped due to the the coldest month of the year. insulating value of the snow(the snow becomes an insulat- Roofing tile Shingles s Roofing paper(I perm or lower Roofing paper /" ' vapor�Mutl betested by thin SOnle e t ..„,.- Batt n511 abort dst Iletl With /''''`,, R 19n p required installed with / wre sraYS or twine / �',''`,a`, R-5 goy insulation(vertical d htal Roel sheathing ��t itt% �` Joints n e r9 over o an' gl i 1�"�� -a i I T ��' � -at Roof sheathing ' I11� r- talk Sealant i e First urace heie uq s_r::. Rigid neulafion Ir L�p` s1�nM1Wlis neM1eat�M1rn. SNcro '.. \ notched around roof I a t �G UMa edbail insulation trusses and sealed a/ WA a Reid insulation(taped, f �� Gypsum beard with vapor Vinyl or I =vl Unlaced ban insulation shiplapped or sealedimMs) S• smipermeable(latex)paint aluminum siding �� Gypsum board wan vapersemi- Rigid mr Rieidlnswalion(taped, l ► permeable(latex)paint sniplpped or sealed)runts) la° 100 ao 90 Mea monwy woortemperature m 00 1 rp Flrmicondensing suriace _temperature or r o o fsheaNiig)itR-5nwq70 Mean monthly outdoor Sa mTereNeDew t LL a150%aH..IPF S A SaIrI iap el 71,F, point temperature E 30 1 PE sea RH paw peim rempearlrr. `_ 40%at R.H..70.F 2020 In10 00 APR MAY JUN JUL AUG SEP OCT NOV DEC JAN FEB MAR APR MAY APR MAY JUN JUL AUG SEP OCT NOV DEC JAN FEB MAR APR MAY Monty Month Figure 3 Figure 4 Poteallel for Caelonsatlon In Phoenix,Arizona wOh Unvamd Root Potential for Condensation la Dallas,boas Mk Unmated Roof and •1,750 heating degree days Sibling Sheathlnu •Winter design temperature 34°F •There is no potential for condensation on the underside of the roof •Summer design temperature 107°F dry bulb;71°F wet bulb sheathing until moisture levels exceed 40%RH at 70°F •There is no potential for condensation on the underside of the roof •Rigid insulation is recommended in this roof assembly to raise the sheathing until interior moisture levels exceed 50%RH at 70°F condensation potential above 50%RH at 70°F Y 2004 Building Science Corporation 4 ing"blanket").In essence creating a vented-unvented hy- brid roof assembly. Note that in these types of unvented roof assemblies(ex- cept Figure 7),interior vapor barriers(Class I vapor retard- ers)are not recommended as these assemblies are expected to be able to"dry"towards the interior. Instead of installing rigid insulation above the roof deck to control condensing surface temperature.air-impermeable spray foam insulation can be installed in direct contact to the underside of the roof deck to accomplish the same thing. Figure 8 shows a roof design where air-impermeable spray foam insulation is installed in direct contact to the under- side of the structural roof deck. Shingles Roofing paw n pail Of lower vapernmrder as— \ In Climate Zone 6 and Climate Zone 7 the air-impermeable ''54°t'^°HvbomTM° 1Y8`$"'ae°memn°61.mws+ insulation,including any covering adhered continuously to 54°567'9 m w the bottom side should have a vapor ermeance of Ipeon A's aa' m row (vertical and no new P Pmate a n nrgf or less(i.e.have the characteristics of a Class II vapor re Plywood or 055 nail base for far shingles .A slarder or lower).This can be done by applying vapor bar- r grownga soiree rests iA tier paint over the interior surface of the low density spray Root she•mno- � foam or by installing a material layer that has a vapor per- 2x10leer— condonsng sun ace meance of I perm or less. _, A hih densityspray foam insulation due to its im rine- -Gypsum g P Y PC Gypsum board ih vaptrr ability properties can be installed directly under roof decks in Climate Zone 6 and Climate Zone 7 without any addi- U" 48 MIMS hit Ann* tional provision for vapor diffusion resistance. •Two ld erS of 8-e'5/inch rigid insulation yielding a total combined thickness of 2.5 inches In Figure 9 extruded polystyrene of thickness l-inch is in- •Layers of rigid insulation have staggered joints lo facilitate airtightness', stalled to provide a Class 11 vapor retarder on the bottom two layers aepreferablelo one layer Cuero Release in airflow resistalee side of the low density air-impermeable spray foam insula- tion.This allows the assembly to be constructed in Climate Inside Monthly Average Temperature of Zone 6 and Climate Zones 7.Without the extruded polysty- Temp. Outdoor Temp. AT Condensing Surface rene layer(or without a coating of vapor barrier paint)the — useoflowdensityair-impermeable spray foam insulation Oct 70 55 15 60 is limited to Climate Zone 3 or lower. Nov 70 45 25 54 Gypsum board is used to provide a thermal barrier with Dec 70 36 34 48 foam insulations to meet code requirements when an attic Jan 70 31 39 45 space is occupiable. Feb 70 34 36 47 Mar 70 43 27 52 Apr 70 49 21 56 Ratio of thermal resistance above condensing surface to total thermal resistance: 16=46=6348 Temperature et Condensing Surface a(AT x 0.3481 a 0utdoorTamperature Figure 5 Conduslin Solace lbmperalures In mailmen,U.C. •The greater the thermal resistance in the cavity,the Iowa the temperature of the condensing surface •The greater the thermal resistance of the rigid insulation,the higher the temperature of the condensing surface •In designs with no cavity insulation,only rigid insulation,yield the highest(warmest)condensing surface temperatures •In hMannnb,mixed-humig and marine climatesal perm or Power vapor retarder as tested by the wet-cup procedure should he Installed under the asphalt roofing shingles 02004 Baffin Selene.CmperatiOn 6 cow densly spray loam insulation S \ ndingseammeta4Wt fl - Papaz Ccscr are.WNad,ared Z. Mrentranewaterpeeehng¢a.toe A Watel Sl la : —Metal cap 1 %PS9dnsul l ///1B'widemembrane stip under Irl vapor c • / parapet I olda ge dawn Over exterior F Aon d' / OSB `Coping adDu OSB sheatkng / OSB RgdtamawmParmW. / li. i RMbee;Wellt) membrane Fiber Lament scupper l abrrescrct Gypsum TWO layers osB aMl / .U. repined t RYh density spray trl8 � pt ••::7 gro+aing tarp Illation 1�e N saNnl to pa betrnd PoIY Miffed(PM) Gypsumboard with semi. mji�� drtp ad n 11llb nee traditional cement.Wen pe btBtoK(paint B m601111°0.6111 ae M t dl g g v m M lath Sealant. db site ergasket at '' [UnYltionee spxe r� MpW e ks " Budding paper band break 4 I — Mng Or Segal (f Al mw�xM 'Pray town ova Place ._Cacty rxpiator, Ftgure 9 Figure 11 Mr amanamtable Spray Foam Imola* Satt®bd Flit Int Asaamlly •Spray foam protected with thermal barrier in occupied attic space •There is no potential for condensation on the undersideof the root •Interior vapor retarder(Class II)required with low density spray sheathing until interior moisture levels exceed 50%RH at 70'F loam in Climate Zones 6 and 7 •High density spray foam insulation does not require an interior vapor retarder in any climate Gypsum board(thermal Darner)required PC tai-rating Asphell shingle tool / Pooling paper \ . Root sMaNb3 /.%'': �t IS' k Forane WC �r underparapet folded Air hazier High density spray foam insulation / Metal cap xtdo[ embrene 4,;..._ h„s rigid insulation (membrane .CSW 3w'el&e co-ka ool4 /.r •• 0.513 sheathing y I Rigidi. bb frig cl M ;houtu Yrf PPe m b ps bale ng I pwrE all Drip edge lucked - -- Mer membrane ohne ... ti u 7 t ! I I ( I " [ S f t (r yW Iaho .. _. Gsn It fl ' ' ar li OccupiablespaceSealant ...g...-..............- c,,.: Open head pint Polymer d1ed(PM( [[[aces _Gypsum boartlINs i £ (every other trek) tractional" m t permeable gawp)gym Ea Blink veneer Kigh density Spray Foam Metal lath Sealant adhesive Cr Bask t Gypsum boaN . Ca Ones nstea§an brk edrmM. . !jCavity ace i over drainage � l mNeOon Plane —.. IpSula(n9 sheam ig BI Dralnugd Plane wo Stcictral sheathing "k ' Figure 12 Flat R —Comiessbm%cutin.Tommamtere Figure 19 Controlled Mr Impermeable%pray FOam Insulation •The thickness of the rigid insulation at both the roof deck and roof •Spray foam protected with thermal barrier In occupied attic space perimeter is determined by a calculation procedure similar to •High density foam insuiaton partially fills roar ratter cavity and Figure wall cavity •mhe colder the climate the thicker the rigid insulation required •No interior vapor retarder required In any climate zone with high •The higher the interior moisture level the thicker the rigid density spray foam insulation insulation required 02004 Building Science Corporation 5 o scw M mg paer 0ceuamasrvapwre*snee es MIMI y Ma ws4wp pagMore required in some d ineteM FSMI cavity Insulation ss RIS MOM inwl tb (verfisai and horizOrMIshingles Idea offset hymn roof nM1 thng) Plywoodm0SO stSI wav for sing; Roofing paper screwed alx yh MO.msulaims falsbers �� R-40rigidtnsNaton(6T,ches- ROM sheatn g of RL9lnch rigidinsulation)in 2x10 rafter COMnsing surlac two or three layers wnh horizontal and vertical joint staggered / GypSAmtoard 4th vapor Nail base for atlingles(plywood or 0.48) peOneave msext psm screwed through ngat mseaton 4....4e to to weeddecking Of timber ratters Air barrier membranea .,- (sheet polyethylene, 1.91 RnyenUl Reel Assembly membrane rooting in very cold and cold •Two layers of R-6Stireh rigid insulator,yiidtog a total combined cemates,houeewraps. y"� thickness of 25 inches buadiig paper w all se ,—Woad dearng •Layers of rigid insulation have staggered Joints to facilitate air tightness', other aamatne) two layers are preferable to one layer due to increase in air flow resistance Timber rafter or exposed joist Figure 7 ,o° _ Cemlal amm/R Reat Assembly w &value increased to R-50 in very cold climate zones to control ice-damming eOIJpIi!!ruu.flsagoWinn. Optimum roof assemblydesign to enclosepool areas and spas tP iB fo d'msmation.a.w cacao • p 9 p ]9 kw!Yan wlm JOF muscle az suis O S 11111 Gso um ,• wan monthly ouafoav�,10211 All ■ tdmPeratare—_ s dr . • OS 10 11!•••• ■ ■■ Low density spray foam insulation \ APR MAV AVN AUGa SEP 001 NOV DEL JAN NES MAR AP MAy MOM sn pl 5 \ - Month RooMS OM`ll a ua 4 as ted by th wpprocedurelflaredrn • Figure 6 some m tl cn„ Pelemlel for CnHnsatlen In Washlnalen,R.C.web mIN Mullen Raaf sheathing- i+'.;t`^ '{'`_„. { 0W7eetel Reef to forcondensation until interior moisture Rased fNM ~� Mr • here is no levels exceed 4potential F during)he cal intest rior of the fardaaadam year if R-16 rigid insulation is installed over a rafter cavity Fmr wmenf acre tNonaawplato insulation to 6-30 Roan nmdeynta j j i* r M9Le •Inhot-humid,mixed-humid and marine climates a l perm or lower sealed to dnpeNO frs'�S"' vapor aardetas tested by thews-cup procedure should be irstand � t — under the assphaltroofing shfngles • a b&dwdake+pze • cupieespaweomnoeP,I nwga Mm space) Figure B MP Intrinall7 Ira Ram i • Spray foam protected with thermal barrier in occupied attic space •In hot-humid,mixed-humid and marine climates a 1 perm or lower vapor retarder as tested by the wet-cup procedure should be installed under the asphalt roofing shingles e1/25/2006 12:53 1413562221e WALNUT HILL PAGE 01 NinSNMI Milan umi N eavw.Masawwas•1ptilrat-3mo pot Minks 111114.4.1“.IM,alec •' Jutuary 25,2006 Building Inspector: Subject: New Building Product. P2000 Insulation and Wind& Water Barrier. Walnut Hill Metal Roofing Supply&Distributor has been given thy dlsttibutanldp fb tbls new product: P2000 Ivulatlon. M manufacs ser,Perk*Steel Frame Building of St. Joseph,MO. has recommended that a Dopy of the specifications and a sample be sant to all binding inspectors. This will allow you to see and eveJuate the product as to building code,fire,smoke,awiratmamal ,ect. We believe P2000 Insulation is an excellent product that is far superior to fiber glass insulation and Tyvek wind and water barrier. P2000 Insulaticm is also cart saving for the contractor in tabor and rime as well ar for the homeowner in hest and ekeuic costs. For any questions,Please call a go online to W W W.P2Insulationoom. Thank you. ' Sincaely, • Erwin and Scott Brown Insolation Systems • DATA BOOK Reflective Rigid Foam Insulation (Self-Taping PRO-LOC.System) 2,PRODUCT INFORMATION SHEET • PHYSICAL DESCRIPTION • PRODUCT DIMENSIONS • PRODUCT STYLES Page 2 3.PREMIER:- 1323-3-, WHITEIEPS1R}IL -Noel x S sheets laminated on one side with foil/scrim/polyethylene and on the other side with foil-backed white polypropylene with scrim. Pages 3,4 4.BASF • Building Code&Specification Compliance Page 5,6 5.BUILDING CODE PROVISIONS • Code compliance and Hazard Rating information Page 7 • ASTM E841U BC 431 FLAME SPREAD and SMOKE DEVELOPED Page 7 6.TAPE: • Vrscor,Inc Page 8 • Tape Products Company Page 9 • Song Adhesives,S. Page 10 I ASTMC 236 GUARDED HOT BOX • Winter conditions Page 1I • Summer conditions Page 12 8.TESTIMONIAL--50%Savings or 50%more effeceive,. Acid Bath TeS1 Results Page 13 • Cebu Poultry Breeding Farms Page 14 • INSULEOAM PRODUCT HIGHLIGHTS Page IS Nur :ti PRODUCT INFORMATION SHEET 3.:'n�R� +v�+.r_:,+AG�`.a �. .,, x'0.'S�SSr Aft:-.:.ttP:--runs Bk., b^ �. •••. ':'� Reflective Rigid Foam Board Insulation (w/The Self-Tape Skirt ProLoc-System) P rs/' ) rip ' n Each sheet is comprised of the following: ✓ Expanded Polystyrene Foam Board ✓ Foil scrim polyethylene Facing (2 facings) or ✓ Foil-backed White Polypropylene Facing ✓ Laminated and glued on both sides • I"Self-taping Skirt ProLoc-System *W Product Dimensions Each sheet can be order in the following dimensions: STANDARD r 4'x 8' 4'x 9' 4'x 10' -1"-2"-3" **Custom orders are also available in the following: Tx 4' 4'x 11' 4'x 12' 4'x 14' 4'x 16' 4'x IS' Product Styles: i P2000 is available in the following styles: P EQDI!`11 lflrlpl< .. -;nun A$11 PREMIER PRODUCT NAME THICKNESS DIMENSIONS FACING • BRONZE 2K INCH 4'X GOLD 2K 5/8 INCH 4' X 8' BOARDS Foil/EPS/Foil or W hite/EPS/Foil • SUPER 2K 1",2",3" INCH 4' X 8' BOARDS Foil/EPS/Foil or White/EPS/Foil 2 4 P2000 OLYMPIC SERIES - DELUXE ,,$�az mt Ai .� <,- ,.« '11,r i res 7 a r z ° 3.° r/� Product: Two-sided Reflective 99% pure Aluminum foil, reinforced scrim with 1-2-3 inch EPS Rigid board. "FOIL - EPS - FOIL" 5n5 FACING COMPOSITION DESCRIPTION VALUE(ENGLISH) VALUES(METRIC) FOIL ALUMINUM(SILVER) 0.0003 INCH 7.6 MICRONS REINFORCING 131-DIRECTION FIBER 1 8 INCH (MD) 7/100 MM(MD) ADHESIVE FLAME RESISTANCE FILM POLYETHYLENE 0.0015 INCH 38 MICRONS PHYSICAL PROPERTIES TEST METHOD VALUES(ENGLISH) VALUES(METRIC) BASIS WEIGHT SCALE 13.7LBS/1000Fr 66.SGM/M14 PERMEANCE ASTM E96 002 PERM 1.15 NG/N' TENSILETEN BURSTING ASTM�36 38 LLBS/WCH 2.5 KG/Mhe 2.5 (MD) ACCELERATED AGE 30DAYS 12 NO CORROSION NO CORROSIONINA 95% 01790 F(49°C) NO DELAMINATIONXIBLE NO FLEXIBLE TION LOW TEMP RESIST. ASTM (-40°C)10°0 REMAINSO LE REMAINSFIAN -40°F @RDELAMINATION NOADELAMINATIONSFEXIBL HIGH TEMP RESIST. 4 HOURS° REMAINSO FLEXIBLE REMAINS DELAMINATION 240°F UIS°C) NO DELAMINATION NO DELAMINATION WATER (IMMERSION) 24 HOURS(�73°F(23°C) 0NO0 DELAMINATION NO DELAMINATION EMISSIVITY(FOIL) ASTM E408 003 003 PHYSICAL AESTHETICS THICKNESS COLOR FORM J FOIL 00003 INCH SILVER LAMINATED FOIL EXPANDED POLYSTYRENE I INCH WHITE FLEX FOAM BOARDS FOIL 0.0003 INC SILVER LAMINATED FOIL MATERIAL SAFETY DATA SHEET FOR EXPANDED POLYSTYRENE (FPS) PRODUCT INFORMATION INGREDIENTS PHYSICALMDATA FIRE AND EXPLOSION PRODUCT GRADES HAZARD.ENTANE COMPONENT FORM FLASH POINT TYPE l LI,D AND DC PENTANE RIGID CELLULAR 610°MIN. CHEMICALPOLYSTFAMILYNEWEIGHT LHAN2%TpGE BLOCKS,BOARDS METHOD 192D9 POLYSTYRENE LESSTHAN2% COLOR ASTGUSH THERMOPLASTIC NON-HAZARD COMP. WHITE EXTINGUISC MEDIA POLYMER FIGHT RENE ODOR Water Fog,Foam on an CAS03-53-iER k: WEIGHT HYDO CART Dioxide,aFoam and Dry 90098%min HYDROOINTON Chemical CAS NAME: BOILINGN/ POINT SPECIALIGTIFIRE BENZENE,ETHENYL NIA INSTRUCTIONS BOMOPOLYMERNG MELTING°TPOINT20° INSTRUCTIONS FORMULA IIS°T0220° Use uRaomained (C8 H8)x SOLUBILITY breathing apparatus INSOLUBLE IN respirator. WATER AUTOIGNm0N TEMP. 850°F MIN. 3 P2000 OLYMPIC SERIES - PREMIER Product: One side White/foil backed and One side foil Reflective 99% pure Aluminum foil, reinforced scrim with 1-2-3 inch EPS Rigid board. ilarainalMili Mill FACING COMPOSITION DESCRIPTION VALUE(ENGLISH) VALUES(METRIC) POLYPROPOLYLEN FOIL ALUMINUM(SILVER) 0.0003 INCH 7.6 MICRONS REINFORCING BI-DIRECTION FIBER ILS INCH (MIT) 71100 AIM(MND) ADHESIVE FLAME RESISTANCE FILM POLYETHYLENE 0.0015 INCH 38.1 MICRONS PHYSICS! PROPER'NES TEST METHOD VALUES(ENGLISH) VALUES(METElc) BASIS WEIGHT SCALE 11.9 LBS I I000FT' 57.9 GM/M' PERMS/INCE ASTM E96 0.02 PERM 1.15 NO/Ne URS /NC STRENGTH ASTM D774 70 PSI 2.8 KO/CAP TENSILE STRENGTH ASTm CI136 16 LBS/INCH 3.2 KN/M(MD) ACCELERATED AGE 30 DAYS @ NO CORROSION NO CORROSION 95%RH,1200 F(49°C) NO DEI.AMINAHON NO DELAMINATION LOW TEMP.RESIST. AST(D 1790 REMAINS FLEXIBLE REMAINS FLEXIBLE -10°F (AVE) NO DELAMINATION NO DELAMINATION FHGH TEMP.RESIST. 4 HOURS @ REMAINS FLEXIBLE REMAINS FLEXIBLE 240°F(116°C) NO DELAMINATION NO DE]AMRNATION WATER IMMERSION 24 HOURS@73°1(23°C) NO DELAMINATION NO DELAMINATION NW..- EMISSIVITY(FOIL) ASTM E4W 003 0.03 PHYSICAL AESTHETICS THICKNESS COLOR FORM WHITE POLY/FOIL 0.0003 INCH WHIIF,ISILVER LAMINATED FOIL EXPANDED POLYSTYRENE 1 INCH WHITE FLEX FOAM BOARDS FOIL 0.0001 INC SILVER LAMINATED FOIL MATERIAL SAFETY DATA SHEET FOR EXPANDED POLYSTYRENE (EPS' PRODUCT INFORMATION INGREDIENTS PHYSICAL DATA FIRE AND EXPLOSION PRODUCT GRADES HAZARD.COMPONENT FORM FLASH POINT TYPE L VI,I AND IX PENTANE RIGID CELLULAR 610°WE. CHEMICAL FAMILY WEIGHT PERCENTAGE BLOCKS,BOARDS METHOD USED POLYSTYRENE LESS THAN 2% COLOR ASTM D 1929 THERMOPLASTIC NON-HAZARD COMP. WHITE EXTINGUISH MEDIA POLYMER POLYSTYRENE ODOR Won Fog,Cm/ma CAS REGISTER/I: WEIGHT PERCENTAGE VERY SLIGHT Dioxide,Foam and Dry 9003-53.6 98%min HYDROCARBON Chemical CAS NAME BOILING POINT SPECIAL FIRE BENZENE,ETHENYL- N/A FIGHTING HOMOPOLYMER MELTING POINT iNSLRUCTIONS FORMULA 175°TO 220° Use self-contained (CS H8)4 SOLUBILITY breathing apparatus INSOLUBLE IN tapir-atop WATER AUTOIGOMITON TEMP. 850°F MIN. NY/ 4 • Technical Bulletin E-8 Revised January 1993 Building Code & Specification Compliance Introduction: EPS insulation manufactured from BF & BFL grades of Styropor expandable polystyrene has been independent-laboratory-tested to show compliance with Model Building Code, Factory Mutual, Federal, and ASTM material requirements Further, EPS insulation manufactured from styropor has been tested to establish compliance with perscriptive applications permitted by code and insurance authorities. Test results, sources, and code/insurance references are summarized below. Section I Materials Requirements ---ASTM C578 BASF Styropor (EPS) RIS Gd M " Vfa p,� Ti1:01126 P4WS 11-95%Mat HAt O09011PS% OffilI.h. 99F IS T�011013 Vbm VaporVaporTaIra-Imam Cffi Twe 10%05.04M 171 WTein1122355 mars--fl al TW1361M Op1N 9M%4 Tani Rffim i] 618 THp1-&O1 TW0111B Drtgieciaexca BASFPolymers 5 Section 11 Minimum 600F flash ignition Section III Material requirements- and 800F self-ignition System requirements-- Model Building Code: ratures 3.Compliance tests-Us. Building Codes A. Surface Burning Testing Report#A-44318 in A.Roof Insulation Without Characteristics accordance with ASTM D1929 Flame spread/smoke 1.Code references Hash ignition temperature 610F development limitaions and BOCA Basic Building Code Self ignition temperature 850F without 14 index thermal bather ASTM E-84 seperation: IC13O Uniform Building Code BOCA Basic Building Code USC Standard 42-1 must comply with FM 4450 (calorimeter test)or UL 1256(30 SBCC Standard Building Code minute tunnel test) ASTM E-84 ICBG Uniform Building Code 2.Allowable code values must meet the requirements of Flame spread 75 maximum " UBC standard#17-4 FM 4450 (genal application) or UL 1256 Flame spread 25 Max SBCC Standard Building Code (special applications) must comply with FM 4450 or Smoke Development-450 Max. UL 1256 D. Crawl spaces B.BTU content,Fuel potential L Sponsor—BASF Corp. 1.Code references Polymer Division IC130 Uniform Building Code Laboratory-SWRI#01-7788- UEC Standard 17-i NFPA#259 2045 SBCC Standard Building Code Test procedure--Full scale NFPA#259 comparative tests of exposed, IS 2.Allowable code values kraft faced r-11 glass fiber ICBG Uniform Building Code insulation vs.3"{ru )EPS SBCC Standard Building Code insulation in simulated crawl a)Backerboard-2,000 BTU per space configuration sqft max.At 12"thickness Test results time of ignition of b)Exterior walls requiring plywood subfloor above crawl incombustible insulation 6,000 space: BTU per sqft max. ---with glass fiber insulation-2 minutes 46 seconds 3.Compliance tests-UL inc. —with EPS insulation 17 Test#R5817183 NIC4864 minutes 2 seconds. conducted in accordance with NFPA#259(UBC Standard 17- Significance model codes call 2) for use of ignition bather over EPS insulation in crawl spaces. Test proves exposed EPS in C.Ignition temperature crawl spaces is less hazardous 1. Code references: than conventional,exposed BOCA Basic Building Code glass fiber insulation ASTM 01929 appllcatioa... 1030 Uniform Building Code- UBC Standard#52-3(ASTM D1929) BASF SBCC Standard Building Code Polymers without test reference `✓ss 2.Allowable code values ICBG Uniform Building Code 6 • ) a h n c, i nr b, m p f5 F r t r° YS r'yi e l I.I. ii, tofu! rt E.�`1 fiz ii trElik `� O U t Frc ,b, U< €i(i''rr �, rt r1 7 t r ,CI!ry hj 1� `..‘4,44%f j fr ,a trtr cr?1.4 PJ VP] i g ' f 04.04 t4. ft fJ£t l ^ p' 'TI � , xo y €IL; G ,-) 't e •f. U w w O N t }`?..,...3N, ( t t} ,r' p Q r, R €� � ,>'5'5'?' a 1 r r 1' , ks Lu L.) 5R= h 4 f t r O c.i 7V" z'5 5555 5,5,5g, x 7i hity� U A Le; j p"f 'a :Da. 44.1 f all ii �` � '3 l'‘ + to k R4 rla E. O n tart r ff Z -++- i , d€!oir.W 4le. „� Imo, ' O tt €p>F 34.414,44.P#0.44# as Ca 1 �' 2 V t 4F� �j1 €tp14 011, r apo I rwrf U T O it* ' )t € rau€F Ws jai, g v Fila €+�r ! - i �nW+ 4 4 0 8 .g v t;; sF t t I i„ y4e, pf OD 1: ! N F-, :� 0 II r"` v' ` T• tx 'int+ ;ev �ira••4 A 4 it � eg FI: ��yy t 'J t Si 'I l` OD A Ct A € ;;;;;;;„,;;$,;;;,,;4.5,<<;d t f a Qaaa , v h T A y PRODUCT INFORMATION SHEET Tape Products Company, IDEAL TAPE CO. WHITE METALIZED POLYPROPYLENE TAPE : WMP 421- WHITE{xvAC) PRODUCTDL.SCR'IPTIOV c4 WHITE ME TALJZED POLYPROPYLENE SCRIM HAS A KRAFT BACKING AND RUBBER BASED ADHESIVE WITH RELEASE LINER THIS TAPE IS USED TO SEAM AM)REPAIR METAL BUILDING INSULATION FACING UTILIZING WHITE METALIZED POLYPROPYLENE. AGGRESSIVE ADHESION: ASSURES EXCEL LENT BOND AND LONG LASTING PERFORMANCE EASILY REMOVABLE LINER: ALLOWS FOR QUICK AND EASY APPLICATION EXCELLENT LIGHT REFLECTIVITY: MAXIAHZESINSULA77ONPERFORMANCE TM DIRECTIONAL SCRIM PATTERN: GIVES STRENGTH AND DURABILITY TO THE TAPE. PHI SIC.IL. PROPERTIES ADHESION TO STEEL 85 OZ/IN WIDTH ADHESIVE RUBBER BACKING WHITE METALIZED SCRIM, KRAFT ELONGATION 11% TEMPERATURE RANGE -20°F - 150°F TENSILE 55LBS./IN WIDTH P:I CK:4GLVG LENGTH 150 FEET WIDTH 3 INCHES Tape pe ROLLS PER CASE 16 `�►+' Tape Products Company, 11630 DEERFIELD ROAD,CINCINNATI,01E0 45242 (513)489-8840 OR TOLL FREE 1-800-543-4930 8 PRODUCT INFORMATION SHEETNes -, VISCOR, INC SURESTIK DOUBLE COATED TAPE . . rr SS2200 -SILVER PRODUCT DESC IPIIOX SS2200 IS A DOUBLE COATED TAPE UTILIZING .005 MIL POLYESTER THIS TAPE FEATURES GOO PLASTICIZER AND WATER RESISTANCE. SERVICE RANGE TEMPERATURE OF -40°F TO 170°F WITH HIGH TACK AND MODERATE SHEAR CHARACTERISTICS. SS2200 IS AN EXCELLENT TAPE FOR GASKETING, INSULATION AND VARIOUS MOUNTING APPLICATIONS. PHYSICAL PROPERTIES THICKNESS MILS STANDARD ROIL SiZF UNWIND ADHESIVE 1.5 54" X 750" POLYESTER CARRIER 0.5 60" X 750" LINER ADHESIVE 1.5 60#KRAFT RELEASE LINER 3.5 TOTAL CALIPER 7.0 TYPICAL t:-IL UES UNWIND SIDF LINER SIDF 180°PEEL ADHESION, OZ/IN 68 68 LOOP TACK, OZ/IN 60.8 60.8 SHEAR ADHESION', HRS 5.3 5.3 SHEAR ADHESION', HRS 57.4 57.4 VIS"OR, INC 1266 PROFIT DALLAS TX 75247 214-630-7211 800-275-1320 `4/0 9 J�tt6ll� 1 1Mialect, ise& "Stick with us" BSA 637 PRODUCT: BSA 637 TYPE: HOT MELT PRESSURE SENSITIVE SOLIDS: 100 % SOFTENING POINT: 187 Degrees Fahrenheit (Approx.) VISCOSITY: 4000 CPS Q 350 Degrees Fahrenheit(Approx.) SPECIFIC GRAVITY: .97+-.01 COLOR LIGHT AMBER USE TEMPERATURE: 300-350 Degrees Fahrenheit APPLICATION: Extrude, roll or spray * sprays very well SOME SUGGESTED USES: EPS Foam to Corrugated and itself Poly Film to itself and other surfaces Typar to Typar,Kraft to Poly Foam Bonds to Typar to paper to Polypropylene Foam have withstood 100 hours in W eatherometer- ASTM G-23. *S*****************************,**************,*S*** *********45************* NOTE: The data presented is based upon tests believed to be reliable:however, manufacturer does not guarantee its accuracy or completeness. Manufacturer will assume no responsibility for the results obtained or for incidental or consequential damages arising front the use of this data. Customer is responsible for determining suitability of this product for his needs Components contained in this product conform to FDA regulation 21CFR175.105 as it concerns indirect contact to food. L 10 Center For Applied Engineering,Inc. Page 3 of 3 sir Matenals Testing Services • Client: Perka 2000 Insulation, Inc. Table 1: Thermal Performance of Perka 2000 Reflect-Sulation Roof System ASTM C 236 - "Guarded Hot Box" Perka 2000 ReflectSulation Average Test Results - Insulation System (Wnter Conditions) (Heat Flow Up) T� = 45.0 ±2°F Hot Air Temperature °F 89.8 Hot Surface Temperature, °F 83.6 Cold Surface Temperature, °F 4.0 Cold Air Temperature, °F -2.0 Mean Temperature, °F 43.8 Average Power, Watts -- 112.16 ,0010 Hot Surface Coefficient, Btu/h ft2°F 1.72 Cold Surface Coefficient, Btu/h ft2°F 1.77 Thermal Conductance, Btu/h ft2°F 0.134 Thermal Resistance, h ft2°F/Btu 7.5 Stanley D. Gatland B I Research Engineer Materials Testing Services �(�\'('M^^II11LL t((uf IS�III This wort for No wanatin d the meet i maybe used 45 m:of rw nig°uNose LtsscuFIrg pocket acWar.o moon U! V V��J dnh constierledaFGN+Lxvlaorlies:nmwvw.Iwrgvn or me name d Gamer For p'l'ied Eylnzermg.Inc slaM o Bused 11 0 LV' P°°Iay or a°reluing. Accredited by the Natonal Institute of Standards and Technology.National Voluntary Laboratory Accodiiaucn ACCLUSTICAL,FIRE,PHYSICAL AHO Program for selected test methods for Acvsical Test Services and Thermal Insulation Materials. THERMAL IJEASUPE ME NTS LABORAI ORE S CCenter For Applied � Engineering,Inc Page 3 of 3 sa MorenaLs Testing Semces `o Client: Perka 2000 Insulation, Inc. MIS Job No.: 257436-B Tahle 1: Thermal Performance of Perka 2000 Reflect-Sulation Roof System ASTM C 236 - °Guarded Hot Box" Perka 2000 Reflect-Sulation 1 Average Test Results -Insulation System (Summer Conditions) (Heat Flow Down) Tom° = 85.0 ± 1°F Hot Air Temperature °F 101.3 Hot Surface Temperature, °F 100.0 Cold Surface Temperature, °F 71.6 Cold Air Temperature, °F 70.4 Mean Temperature, °F 85.8 Average Power, Watts 24.43 Nue Hot Surface Coefficient, Btu/h R2°F 1.78 Cold Surface Coefficient, Btu/h ft2°F 1.93 Thermal Conductance, Btu/h ft2 aF 0.082 Thermal Resistance, h ft2°FfBtu 12.3 `e• Stanley D. Galland II Ow 4, Recearch Engineer Materials Testing Services 12 This IFan a la MAB INomx,°n tl Pe QenLA flu UQ nY VN°r,la Jn Paws G tacos,nitduux Wlvre inn Sul y+uillOd a iuno.M.l°.ew.TN. otm,ren,a Caner,a Wad prong.am hfl nm he died qw.i I_pidlnly v advancing Ai:coedited by Me HauwpI humid of Slanaaras and Technology.Nampa!Volomary Labs:mom kaedimum ACIX151 CA1 FRF.PHYS CAL Atte Plegram ist selectedles[methods kir Aciossol Test Semites coo Thesmai hs)a°n Ku zs. LFERM4 SACASI.AEA'AIITS LAbOPitCH SCS • GUSTOfir • G l Z9 ave Travers y Steve Stephens 55 13-61600 a+ I' O 313-3858929 1103 S.E Lakeview Or. Sebring, Florida 33870 October 12, 1997 Perka-2000 Reflect-Sulation Mr. Jeffrey K Ludwig - ABC FrameTech,Inc. Sebring,Florida 33871-1215 Dear Mr. Ludwig: As you know, I operate a tanning business which uses many corrosivechemicals that run the "ph" scale from 1 through 15. Business is booming and we will start construction on a new facility early next year. An important consideration for my new tannery is finding building materials that can withstand continual exposure to corrosive chemical filmes. At your urging:,I decided to put P-2000 Reflect-Subation to the test: To my way of thinking, there would be a double bonus if your rigid insulation panel passed this test. Furst, Fd have an insulated wall surface that resists chemicals,is easy to repair,and does not require a lot of Nvad maintenance. Secondly,I could substitute lower costing IJ&for 5/8" sheet rock as a backing material, eliminate the cost of standard insulation blankets entirely, and forget about expensive elastomeric paints. Two of the strongest chemicals we use are sulfuric acid and formic acid. For the P-2000 test, a solution of each acid was prepared in a5-gallon bucket at the density we normally use for tanning hides. Next, 6"x6" samples of the 5/8"P-2000 Reflect-Sulation with fol/white backing were put directly into these acid solutions. The results were absolutely amazing: After 3 weeks of daily stirring, turning, and dunking in this acid bath, there was no damage to the rigid foam or laminate baddna of the P-2000 samples!!! After seeing these results for myself I am convinced P-2000 Reflect-Sulation is a superior product which is far more durable and versatile than other insulation products on the market. Respectfully, - David Travers, President Sebring Custom Tanning 13 E 7/ • Coldham Architects, LLC Tel:413.5493616 Fax:6802 155 Pine St. Amherst, MA 01002 www.ColdhamArchitects.com jj//YY MEMO To: Steve Ferrari •• Kohl Construction From: Thomas RC Hartman,AIA _ Cc: Mr.Tony Patillo Building Inspector Date: 22 Feb 2006 Project: 02-03 RHC Subject: Unvented cathedral ceilings Mr. Ferrari, Please proceed with deleting the venting channels from the roof assembly of the Common House at Rocky Hill Cohousing. We will retain the poly vapor retarder on the interior of walls and ceilings as originally contracted. I have spoken to the Building Inspector and provided backup information in reference to this alternate material and system, and have assured that an air barrier will be properly installed and blower door tested. Please do not hesitate to call with any questions. comcere as RC ' :.• -n ,AIA Page 1 of I