This invention relates generally to a method and apparatus for insulating walls, particularly subsurface walls, that provides improved flame retarding performance and which may also provide improved moisture control at the interface between the insulation material and the masonry wall. More particularly, this invention pertains to an insulating process and apparatus in which at least one flame retardant layer is incorporated into an insulating system in combination with insulating materials for finishing walls and, for exterior or other cooled spaces, optionally including at least one layer of sorbent and/or wicking materials, for finishing walls.
The exterior walls of a building are typically insulated in order to reduce the heating and cooling demands resulting from variations between the exterior temperature from the desired interior temperature. A wide range of fibrous, solid and foam insulating materials have been used to achieve this insulation, with a common insulating material being faced or unfaced batts of mineral or glass fibers. Interior walls, e.g., walls that divide or define separate smaller spaces within the area bounded by the exterior walls may also include similar types of insulation for reducing heat and/or sound transmission through the walls.
When using a faced insulating product in which a facing layer, such as asphalt-coated Kraft paper or a polymeric film, is adhered to the insulating layer, the insulation product is typically installed with the facing layer positioned toward the interior space. This orientation tends to reduce infiltration or diffusion of the moisture-laden interior air through the insulating layer to the interface between the insulating product and the exterior wall. Particularly in climates with long heating seasons, high humidity and/or extremely cold temperatures, using faced insulation products limits the amount of moisture from the interior air that can reach the cooler exterior wall and condense to form liquid water on the surface of the exterior wall.
As used herein, masonry walls include constructions utilizing clay brick, concrete brick or block, calcium silicate brick, stone, reinforced concrete and combinations thereof. Water present at the interface between the insulating product and the inside surface of the exterior wall and/or the outer portion of the insulation product is associated with a host of problems including mold growth, efflorescence, reduced insulating efficiency and, if sufficiently cold, frost spalling resulting from water freezing and expanding within cracks and gaps in the masonry.
A major contributing factor to the accumulation of water at the interface and the resulting decreased performance of the associated masonry wall system is the leakage of warm humid air through the building envelope to surfaces that are at temperatures below the dew point of the adjacent air and the associated accumulation of condensation within the insulating layer and/or on the inside surface of the exterior wall.
Further, the use of such finishing and insulating systems for finishing residential basements can result in the materials being placed in general proximity to heated surfaces and potential ignition sources such as furnaces, boilers, water heaters, space heaters, etc. In recognition of these applications, the selection of and particular combinations of materials incorporated into such finishing and insulating systems should serve to suppress ignition and/or flame spread.
A need thus exists for improved systems and materials suitable for finishing and insulating both interior and exterior walls, that provides improved moisture control, particularly moisture resulting from condensation of water vapor on cool surfaces and improved flame retarding properties.
To solve the problems outlined above, the present invention provides an insulation product and an insulation system incorporating a flame retardant or fire inert filler material layer. The flame retardant layer will typically comprise a fiberglass mat into which one or more flame retardant or fire inert filler materials and/or additives have been incorporated.
As will be appreciated the selection and combination of the fillers and/or additives will be guided by the performance requirements and economic considerations. The performance of any particular combination may further be evaluated using one or more of a variety of industry recognized tests focusing on parameters such as flame spread, smoke generation, etc. to ensure that the product provides satisfactory performance.
To the extent that such products may be used for finishing and insulating exterior walls, particularly masonry walls, or unheated spaces, the finishing system panels may also incorporate one or more layers or regions of wicking media arranged to transport condensate from the interface between the insulating product and a cooled surface, such as an exterior wall, to a more interior location where it can evaporate and/or more or more sorbent material layers or regions for holding condensate. For example, an active layer or layers comprising one or more of a wicking fabric, wicking media and sorbent material may be provided on or near the exterior surface of the primarily insulating layer. When the insulating product is installed, the active layer will be closely adjacent and/or in contact with an inside surface of the exterior wall and thereby positioned to collect and/or redistribute condensate in a manner that will tend to maintain the insulating performance.
The insulation product is preferably installed with a corresponding support element to form an insulation system. The support element will typically be provided along the lower edge of the insulation product and define a space between the insulation product and the floor. The support element may comprise several cooperating elements or structures and may, for example, include a baseboard portion to create a more finished appearance for the interior surface of the insulation system.
This space defined by the support element portion of the insulation system may be used for routing an extension portion of the primary wicking material toward and/or into the interior space in order to increase the evaporation rate. Additional elements, such as vents, grills, fans, ducts, sorbent material, cable channels, secondary wicking materials and heaters, may be included in or connected to the support element for further improving the performance and versatility of the insulation system.
Various objects and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiment, when read in light of the accompanying drawings.
The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which:
These drawings have been provided to assist in the understanding of the exemplary embodiments of the invention as described in more detail below and should not be construed as unduly limiting the invention. In particular, the relative spacing, positioning, sizing and dimensions of the various elements illustrated in the drawings are not drawn to scale and may have been exaggerated, reduced or otherwise modified for the purpose of improved clarity. Those of ordinary skill in the art will also appreciate that a range of alternative configurations have been omitted simply to improve the clarity and reduce the number of drawings.
As shown in
As used herein, the terms primary and secondary insulating materials relate to the relative position of the two layers in the illustrated embodiment with the primary insulating material being closer to the insulated space. Those of ordinary skill in the art will appreciate that the relative thickness and material selection for these two insulating materials can be customized to meet performance goals for various applications. The relative contribution of the two insulating layers to the overall R-value of the insulating product will necessarily vary with their relative thicknesses and compositions and may be relatively equal or may be heavily skewed toward one of the layers. For instance, one exemplary embodiment may be configured whereby the secondary insulating material layer would be rated a R-10 while the primary insulating material would only be rated at R-3 to R-4. The selection of the appropriate materials and thicknesses for a given application may be guided by reference materials readily available to those of ordinary skill in the art.
A second embodiment is illustrated in
The point attachments 80 are useful for generally maintaining the vapor permeability of the two joined layers. In the event that one or more of the layers is generally impermeable to vapor or vapor permeability is not a concern, it will be appreciated that a continuous adhesive layer or sheet (not shown) may be used to attach the respective layers within the insulating system.
A fifth embodiment is illustrated in
A sixth embodiment is illustrated in
As illustrated in
As illustrated in
The flame retarding layer 30, will typically comprise a fiberglass mat that incorporates one or more flame retardant fillers and/or flame retardant additives. Exemplary flame retardant fillers and additives include, for example, alumina trihydrate (ATH) (Al2O3.3H2O), hydrated zinc borate (ZnB2O4.6H2O), calcium sulfate (CaSO4.2H2O) also known as gypsum, magnesium ammonium phosphate (MgNH4PO4.6H2O), magnesium hydroxide (Mg(OH)2), ZnB, clay, calcium carbonate, carbon black, acid intercalated graphite, micro encapsulated H2O, halogenated fire suppressants, intumescent phosphate compounds such as ammonium polyphosphate, organic and inorganic phosphate compounds, sulfate and sulfamate compounds such as ammonium sulfate and free radical scavenger materials such as antimony trioxide. Those of ordinary skill in the art will appreciate that this list is exemplary only and that other suitable compounds may be utilized to improve the fire retarding properties of the fiberglass mat.
The flame retarding layer 30, may also incorporate materials intended to reduce radiant heat transfer through the layer. Exemplary radiant barrier materials include, for example, fine metal particles, metal coated particles or metal films that will tend to reflect radiant energy and reduce the heating of materials, such as the primary insulating layer 20, protected by the flame retarding film 30. Thus positioned between insulating layers, the fire retarding layer 30 will improve the fire retarding performance of the insulating system without significantly affecting the handling and appearance of the insulating panel.
When utilized, the wicking material 45 will preferentially collect condensate from water vapor that has diffused through or around the insulating system 1 from the finished interior space, typically a heated room, to a point near or at the cool, inside surface of an exterior wall 50 when the temperature of the wall is below the dew point of the air reaching the wall. Similarly, the wicking material 45 will collect water that diffuses or seeps through the masonry wall 50 from its outside surface, particularly for subsurface portions of the exterior wall that are not completely sealed. In addition to seepage, it will be appreciated that in those regions subject to periods of hot, humid weather, water vapor diffusing from the environment outside the exterior wall may condense as it reaches the cooler inside surface resulting from the air conditioning of the interior space.
The wicking material 45 is preferably a non-woven material that can be formed from a polymer or natural fiber. One suitable polymer for manufacturing the wicking material is rayon. Rayon fibers may be striated, or include channels, along the length of the fiber, which provide capillary channels within the individual fibers so the wicking action does not depend solely upon capillary action resulting from the channels formed between two adjacent fibers.
In addition to rayon fibers, other polymeric fibers including polyester, nylon, polypropylene (PP) and polyethylene terephthalate (PET), may be manufactured or processed in a manner that will produce fibers including striations or channels on their surface. A number of fiber configurations have been developed that provide a plurality of surface channels for capillary transport of water and have been widely incorporated in active wear for improved comfort. These types of materials can be collectively referred to as capillary surface materials (CSM) and include so-called deep-grooved fibers that have high surface area per unit volume as a result of their complex cross-sectional configuration. The capillary material layer can be provided in different configurations including, for example, a non-woven film or a fine mesh configuration.
As a result of gravity, the wicking material 45 will tend to transport any water collected at the interface between the insulating system 1 and the exterior wall 50 downwardly along the interface and, near the lower edge of the insulation product into a terminal portion 45a that may be arranged inwardly toward the interior space or in an opening provided within the base structure 100 to allow for evaporation, collection or secondary removal techniques. Preferably, the terminal portion 45a will be sized or otherwise configured to provide for a removal or evaporation rate for the transported fluid sufficient to avoid or reduce undesirable accumulation of liquid within the insulating system or at the interface with the exterior wall.
There are several methods to form the wicking material which may be configured as a non-woven film and/or as a relatively fine mesh. The fibers can be laid down dry with an acrylic emulsion being applied to the fibers and then cured by heating or UV radiation exposure. Standard fiber binding emulsions such as acrylic or EVA (ethylene vinyl acetate) can be utilized.
In another embodiment of the invention the insulating system of
Depending on the volume of condensate and seepage that are anticipated for a particular installation, the wicking material 45 present in the insulation product illustrated in
As reflected in the figures discussed above, the primary support element 100 and/or the trim element 102 (where shown) may be provided in a larger number of configurations and may be manufactured from a large number of materials suitable for extrusion or other forming techniques such as various polymers and metals. The supporting element or structure 100/102 may be configured to provide one or more additional elements or structures that will tend to increase the rate of evaporation of the water and/or condensate that reaches the terminal portion 45a of the wicking material 45 and may utilize a secondary wicking material (not shown).
As will be appreciated, the secondary evaporative and/or wicking material may assume a wide range of configurations within, and/or partially without, the support element 100/102. It will also be appreciated that the particular embodiments illustrated and discussed herein, while exemplary, are not to be considered limiting or exhaustive and that a wide variety of configurations may be utilized to achieve the desired functionality and/or adapt the insulating system for more and less challenging conditions.
The principle and mode of operation of this invention have been described in its preferred embodiments. However, it should be noted that this invention may be practiced otherwise than as specifically illustrated and described without departing from its scope.