COMPOSITE HOUSE WRAP FORMED OF LOW DENSITY POLYETHYLENE FOAM WITH EVACUATED CLOSED CELLS AND HAVING TORTUOUS PATHS OF THERMAL CONDUCTIVITY

A house wrap for a building comprises a reinforcing drainage plane layer configured to face the outside of the building; a breathable, non-perforated barrier film bonded to the drainage plane layer; and at least one insulating layer including a perforated expanded low density polyethylene foam layer, wherein in the expanded low density polyethylene layer at least 80% of the blowing agents are dissipated from closed cells within the expanded low density polyethylene layer, forming evacuated closed cells whereby a partial vacuum is formed within the closed cells of the low density polyethylene layer.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a composite house wrap formed of low density polyethylene foam with evacuated closed cells and having tortuous paths of thermal conductivity and process for making the same.

2. Background Information

Low-density polyethylene (LDPE) is a thermoplastic made from the monomer ethylene. It was the first grade of polyethylene, produced in 1933 by Imperial Chemical Industries (ICI) using a high pressure process via free radical polymerization. Polyethylene foam, also known as PE and PEF, is a semi-rigid, open or closed-cell type of foam with a near-infinite amount of applications.

Thermoplastic foam products, in general, can be produced by a wide variety of processes, of which extrusion is but one, that are in part responsible for the wide variety of foam products available today. Foams range in consistency from rigid materials suitable for structural use to flexible substances for soft cushions and packaging materials. These foams range in cellular formation from open or interconnecting-cell foams to closed or uni-cell foams. The cell structure may range from large to fine. Electrical, thermal, mechanical, and chemical properties can be varied within wide limits depending on the thermoplastic resin composition and the method chosen to create the foam. Foamed thermoplastics range in density anywhere from about 10 kg/m3 to over 1,000 kg/m3, although the latter perhaps more properly are called microcellular structures. True foams are considered to have a density of less than about 800 kg/m3.

Many methods have been developed for the manufacture of foamed thermoplastics. See for example, in U.S. Pat. Nos. 6,350,512, 6,303,666, 5,844,009, 5,554,661, 5,462,974, 5,348,984, 5,059,376, 5,034,171, 4,952,352, 4,746,564, 4,649,001, 4,464,484, 4,347,329, 4,251,584, 4,214,054, 4,120,923, 4,110,269, 3,966,363, 3,810,964, and 3,067,147 which are incorporated herein by reference. The methods generally can be classified into three groups: 1) methods for adding a gaseous “blowing agent” to the thermoplastic during processing, 2) methods for producing a gaseous blowing agent in the thermoplastic during processing, and 3) methods for forming a thermoplastic mass from granules to obtain a cellular structure. Similar blowing agents sometimes are used in the various methods to produce foams. However, it has been proposed that the effectiveness of a particular blowing agent varies considerably depending on the thermoplastic resin composition, the method chosen, the process conditions, the additives used, and the product sought.

House Wraps

House wrap is a worldwide multi-billion dollar yearly industry. The phrase “House wrap” (also called “housewrap”) has been defined as inclusive of all synthetic materials effectively designed for the replacement of traditional sheathing tar paper. These materials are all lighter in weight and usually wider than asphalt designs, so contractors can apply the material much faster to a house shell. A conventional house wrap is described as functioning as a moisture barrier, preventing rain from getting into the stud wall construction while allowing moisture vapor to pass out from the home's interior living space to the exterior. If moisture from either direction is allowed to build up within stud or cavity walls, mold and rot can set in. Further the fiberglass or cellulose insulation will lose its R-value (a measure of the efficiency of the insulation) due to heat-conducting moisture.

Conventional house wraps have been described as broadly including (1) asphalt-impregnated paper or fiberglass; (2) micro-perforated, cross-lapped films; films laminated to spun-bond non-woven materials; (3) films laminated or coated to polypropylene woven materials and calendared, wet-laid polyethylene fiber.

House wrap is generally described as requiring both a waterproof aspect and it must have a high moisture vapor transmission rate (MVTR) to be effective. It must also take handling abuse during installation and it is helpful if it is resistant to UV light. House wrap is often left exposed for some time after construction, awaiting exterior sheathing installation. House wrap is generally installed over the sheathing and behind the exterior siding. Siding can be vinyl, wood clapboard, and cedar shingles or brick facade. In all cases, the house wrap, generally, is the last line of defense in stopping incoming water or exterior water condensation from getting into the wooden stud wall. For a general background and description of house wraps, see the June 2000 Department of Energy (DOE) publication (DOE/GO10099-769) entitled “Weather Resistant Barriers: How to Select and Install Housewrap and Other Types of Weather Resistant Barriers”

It is known to use micro-porous polyolefin films in house wrapping applications. One commercially available film heretofore used as a house wrap is made of high density polyethylene (HDPE) flash spun into fibers and pressed to form the film. The resulting flash-spun HDPE film has been described as suffering from both a high air permeability and a relatively low tear strength. Thus, such house wrap is subject to damage during shipment and installation.

Another commercially available film employed as a house wrap is melt blown, spun-bonded polyethylene. Like the flash-spun HDPE fiber film, the spun-bonded polyethylene has been described as providing a high permeability to air and even worse tensile properties, i.e. break strength, tear strength and puncture resistance. Thus, there is an unfilled need for a house wrap with both “breathability” and good physical and tensile properties.

U.S. Pat. No. 4,929,303 discloses a house wrap formed of a composite breathable film comprising a breathable polyolefin film heat laminated to a non-woven HDPE fabric. The breathable film is prepared by melt embossing a highly filled polyolefin film to impose a pattern of different film thickness therein, and stretching the embossed film. The non-woven fabric is made by cross-laminating HDPE fibers at the crossing points to form a thin open mesh fabric, and co-extruding a heat seal layer thereon. The composite is made by heat laminating the breathable film to the heat seal layer of the fabric.

The DuPont Company has long promoted its TYVEK® brand of house wrap. The TYVEK® brand of house wrap is sometimes described as being “a sheet of very fine, high-density polyethylene fibers”. It has been suggested that the sheet is produced by hot calendering a web made by a flash-spun process where polyolefin polymer is converted into three-dimensional networks of thin continuous interconnected ribbons called film-fibers or plexi-filaments. This process is asserted to be disclosed in U.S. Pat. Nos. 3,081,519, 3,442,740, and 3,169,899.

U.S. Pat. No. 4,900,619 discloses a translucent non-woven fabric composite, suitable for use as a house wrap, wherein the composite comprises a melt-blown fabric layer laminated to a reinforcing fabric layer and may include tacking strips. The composite may be prepared by calendering a melt-blown fabric and a reinforcing fabric together in a nip equipped with a resilient roll.

U.S. Pat. No. 7,148,160 discloses a composite sheet material useful as a house wrap that is water vapor permeable and substantially liquid water impermeable, in which the composite sheet material includes an outer non-woven fiber layer, a film, and a reinforcing layer.

U.S. Pat. No. 7,393,799 discloses composite sheet material that is moisture vapor permeable and substantially liquid impermeable, the composite sheet material including as layers a lightweight, non-wet laid polyester nonwoven, a polyurethane breathable film, a polymer-coated, high tenacity polyester mesh, and a lightweight, non-wet laid, polyester nonwoven material. The material is also abrasion, tear, mildew and fire resistant.

U.S. Pat. No. 5,308,691 discloses a “controlled porosity composite sheet” useful as a house wrap that comprises a melt-blown polypropylene fiber web having a spun-bonded polypropylene fiber sheet laminated to at least one side thereof.

Some commercially available house wraps are three-dimensionally textured to better channel intruding water away from the structure. Like their smooth-faced predecessors, these permeable products also diffuse moisture vapors from inside the structure. For example, GreenGuard's RAINDROP™ brand house wrap is non-perforated cross-woven (breathable) coated polyolefin scrim wherein woven black vertical strands create vertical grooves to direct water downward. Manufacturing giant DuPont introduced Tyvek DRAINWRAP™ in 2004 that was made of the same non-woven material as its Tyvek® Home wrap, and wherein it has vertical grooves.

The WEATHERTREK™ brand house wrap by Valeron Strength Films, has a non-directional “pebbled” texture finish to funnel water, wherein, because of its overall pattern, it can be installed in any direction, which may save installation time, versus those with vertical channels. It's rough, crush-resistant texture creates a standoff property to allow an air space between sheathing and siding.

As a further type of house wrap, foil-faced house wraps have been designed, such as SUPER R PREMIUM™ brand “radiant” barrier from Innovative Insulation and Low-E™ brand House-Wrap from Environmentally Safe Products. There is some question of the effectiveness of the foil as a radiant barrier after the outer cladding is attached to the building.

Despite the wide commercial acceptance and application of currently available house wraps, there have been those that have objected to their viability and efficiency. Joseph Lstiburek of the Building Science Corporation issued a report entitled “Problems with Housewraps” in 2001 in which he noted that “the energy aspects of [currently commercially available] housewraps are vastly overstated”.

As noted above, expanded low density polyethylene foam has a wide number of applications. The developers of the instant invention utilized LDPE foam in the construction of a house wrap as disclosed in patent publication 2010-0154338, which is incorporated herein by reference. This house wrap application was a three layer LDPE foam structure using a particular LDPE foam that was disclosed therein.

U.S. Pat. No. 11,274,437 is issued from the application published as 2020-0270858 which was identified as being particular relevance to the claimed invention in the search report of the parent case. The abstract describes a draining construction wrap includes a pliable moisture impermeable layer having interior and exterior surfaces. A drainage framework is configured to channel moisture across the exterior surface of the pliable moisture impermeable layer. The drainage framework includes a plurality of support struts. Each of the support struts includes a base strut portion coupled with the exterior surface, a strut support face, and a strut body extending from the base strut portion to the strut support face. A plurality of drain channels are between the support struts. The draining construction wrap includes an installation surface configured for coupling with an outer wall. The installation surface includes the strut support faces of the plurality of support struts. The strut bodies of the plurality of support struts brace the installation surface and the pliable moisture impermeable layer is recessed from the installation surface with a strut gap therebetween.

The search report in the parent application also identified U.S. Patent Publication 2018-0001522 and U.S. Pat. Nos. 8,215,083, 7,984,591 and 10,465,381 as defining the general state of the art.

The above identified patents and publications are incorporated herein by reference in their entireties. These patents describe calendering techniques and composite layer attachment techniques that can be utilized in the present invention as will be apparent form a review of the following description.

Conclusions

There remains is a need to significantly improve upon the operational characteristics of house wraps. It is an object of the present invention to address the deficiencies of the prior art discussed above and to provide an efficient house wrap that can be produced in a cost-effective manner.

SUMMARY OF THE INVENTION

The various embodiments and examples of the present invention as presented herein are understood to be illustrative of the present invention and not restrictive thereof and are non-limiting with respect to the scope of the invention.

According to one non-limiting embodiment of the present invention, a composite house wrap is provided with at least three integral sections or layers. The first or front or outer layer is a reinforcing grid or mesh that functions to form a drainage plane between the house wrap and the outer cladding and thus it will face the outside cladding. The second or middle layer is a non-perforated breathable, barrier film, such as a nonwoven film layer, a PTFE film layer, polyethylene (PE) film layer or polyurethane (PUR) film layer, which is bonded to the first layer, such as through thermal bonding. The term breathable references a structure that allows water vapor transmission. The term barrier with regard to the film layer references that it is resistant or impervious to liquid transmission. An optional third layer is a breathable polyester film which provides an improved bonding layer or adhesion-promoting layer between the barrier film layer and the expanded, closed-cell low density polyethylene layer. The fourth or rear layer is an expanded low density polyethylene sheet or layer with evacuated closed cells in which at least 80%, preferably at least 95%, and more preferably at least 99% of the blowing agents are dissipated from the closed cells.

One aspect of the invention provides a house wrap for a building comprising of a first reinforcing layer providing a drainage plane for the house wrap and configured to face the outside of the building; a second layer including a breathable, non-perforated barrier film bonded to the first layer; and a third layer, including a perforated expanded low density polyethylene foam layer, which is bonded to the middle layer, wherein in the expanded low density polyethylene layer at least 80% of the blowing agents are dissipated from closed cells within the expanded low density polyethylene layer, forming evacuated closed cells, whereby a partial, if not complete, vacuum is formed within the closed cells of the low density polyethylene layer.

The house wrap, according to the present invention, will provide barrier protection plus moisture vapor transmission and yield an insulation R-value of at least R-6. This house wrap is specifically designed to add enhanced insulating characteristics as opposed to conventional house wraps, while maintaining a cost-effective and easy-to-handle house wrap.

These and other advantages of the present invention will be clarified in the description of the preferred embodiments taken together with the attached figures.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention relates to a composite house wrap 100 provided with integral sections or layers 50, 40, 30 and 12 as described below. The house wrap 100, according to the present invention shown in FIGS. 3-4, will provide barrier protection plus provide moisture vapor transmission and an insulation R-value of approximately R-6 or higher.

The composite house wrap 100 of the present invention uses an expanded, closed-cell low density polyethylene foam preferably formed as described in U.S. Pat. No. 11,623,375 which is incorporated by reference herein.

Low density polyethylene (LDPE) is a thermoplastic, with the formula (C2H4)n, which is defined by a density range of 0.910-0.940 g/cm3. The LDPE molecules are less tightly packed and less crystalline than HDPE because of the side branches, and thus its density is lower. FIG. 1 is a schematic plan view of a system for forming the LDPE sheets used in the house wrap 100 of the present invention; and FIG. 2 is a schematic top view of the system of FIG. 1 taken in the direction of the arrow Il shown in FIG. 1.

As schematically shown in the drawings, a low density polyethylene prepared by conventional process is mixed, for example in a hopper 1, with an effective amount of a glyceride, preferably a monoglyceride, forming a degassing agent, to form a dry mixture (as discussed below, in alternative embodiments the dry mix includes a preliminary auxiliary blowing agent, a surface activation agent, a separation agent, a fire retarding agent, a crosslinking agent to improve strength of the foam, a coloring agent and an anti-discoloration agent). The low density polyethylene may be mixed, for example in a hopper 1, with an effective amount of hydrocarbon scavenger additive such as glycerides, activated carbon, sodium bicarbonate, graphite, silica gels, zeolites, diatomaceous earth, and polymer absorbents called “petrogels”: polyolefin-based hydrophobic absorbents that demonstrate selective absorption of hydrocarbon (oil) molecules in water, and mixtures of the above, with glycerides and glyceride-containing mixtures being preferred. Mixed into the low density polyethylene are hydrocarbon scavenger additives that react with the expanded low density polyethylene in a manner that causes short chain molecules of Hydrocarbon Scavengers to have an affinity for hydrocarbon structures of the primary blowing agent, and draw these variants to oxygen-rich environments, namely to the exterior of the composite structure. As the cells deplete, the process slows accordingly and consumes more time to evacuate the remaining hydrocarbon-based molecules than when the process was initiated.

The dry mixture is conveyed in an extruder barrel 3, where it is processed in a series of stages at different temperatures. A conventional thermocouple control box can be used to maintain a particular required temperature in each of the processing stages in the extruder barrel 3. A conventional coil or screw conveys the mixture through the extruder barrel 3. In the extruder barrel 3, the dry mixture is heated at a temperature of about 170° C. to form a melted and softened polyethylene mass. In the extruder barrel 3, the primary blowing agent is introduced at 7 into the polyethylene mass to subject the mass to cell expansion. This primary blowing agent is introduced at a suitable pressure. The preferred primary blowing agent is propane, however butane or a mixture of propane and butane may be used. When using liquid propane as the primary blowing agent, an effective amount of propane is about 15-50% of the low density polyethylene by weight.

After the introduction of the primary blowing agent and expansion of the polyethylene mass, the mass is subjected, within the extruder barrel, to a temperature of about 100° C., wherein it begins to cool. Temperatures of about 100° C. prepares the mass for proper and efficient cutting. This completes the heating and blowing process.

The expanded mass continues its travel through a second portion 8 of the extruder barrel and a desired quantity of the expanded mass is cut, for example, by a conventional cutting blade 9. The desired quantity depends on the size of the final sheet. The cut, expanded mass is next subjected to a temperature of about 105° C. in the extruder barrel and extruded through a die and mandrel 20 into a free expansion zone 10 and cooling zone 11 at atmospheric pressure and room temperature. The temperature of the mass should be raised slightly after cutting because a temperature of about 100° C. is too cool for proper extruding. After extrusion, the foamed polyethylene mass expands naturally in the atmosphere, but not explosively, and cools at room temperature for a short period, e.g., a few seconds. The cooling mass of polyethylene is then formed into a sheet 12 by conventional rollers 13, the thickness being determined by the desired end use of the product.

The sheet 12 can then be wound on rolls 25, after which it is maintained at room temperature (typically 20° C. to 30° C., preferably about 25° C.) for a curing period of 1-30 days, but preferably closer to 30 days. The cells of the expanded mass are degassed as the entrapped blowing agent works its way out of the cells. Typically, more than 99% (actually more than 99.9%) of the primary blowing gas is degassed from the cells and not in the sheet by 30 days. The closed-cell low density polyethylene sheet 12 is available for subsequent processing into the house wrap 100 typically when at least 99% of the primary blowing agent is degassed from the sheet 12.

Testing of the sheet 12 used in the present invention, using propane as the primary blowing agent with a curing time of 15 days, yielded no trace amounts of butane in the samples tested. The testing was performed by Vapor Analysis by Material Characterization Services LLC at the Oneida Research Services facility in Englewood, Colorado in August 2016. The test was performed three times and utilized two control samples. The gas concentrations were measured in parts per million, wherein measurements of Argon and CO2 being registered in separate control samples at levels as low as 7 parts per million, evidenced the accuracy of the testing, and 0 parts per million of the blowing agent were found in the samples of the sheet 12 tested. With the accuracy of the testing performed, this yields a degassing of greater than 99.9993% of the primary blowing agent.

The closed cell expanded low density polyethylene sheet 12 is used in the composite house wrap 100 as outlined herein and shown in FIGS. 3-6, the primary embodiment shown in FIGS. 3-4.

Without being limited to theory, it is believed that the process of forming the low density expanded polyethylene foam 12 creates a firmer cell that keeps the cell structure from collapsing, and allows the blowing agent to fill the cells and then evacuate, through hydrocarbon-philic chemistry, without collapsing the cell structures and, therefore, yields an effectively evacuated cell or vacuum (or technically a partial vacuum). A vacuum is the best form of insulation, and the manufacturing process results in an extremely thin material which is highly insulating as the numerous cell walls create a tortuous path for thermal conductivity. By creating micro cells that are semi-rigid and have or contain a vacuum, the house wrap 100 becomes advantageous for the building industry. With stacking these “evacuated cells” on top of each other (multiple layers 12 and/or thicker layers 12) and creating a barrier to restrict heat or air conditioned airflow. A 1.5 mm extruded composite house wrap 100 produces an R-6 product.

The terms about, approximately or similar terms should be read as meaning within ten percent within this application. This house wrap 100 is specifically designed to add enhanced insulating characteristics as opposed to conventional house wraps, while maintaining a cost effective and easy-to-handle house wrap.

As with most extruded material and prior art LDPE, the LDPE layer(s) 12 of the house wrap 100 utilizes a gas injection process to create a structure of randomized gas-filled spheres throughout the material of the sheet 12. However, unlike any other extruded material or other LDPE structures, the injection gas used to create the gas-filled spheres within the layer 12 is completely expunged from the material during the curing process, thereby creating a unique extruded material. The material has been tested and determined to be comprised of a countless number of evacuated cells without even a trace amount of the injection or blowing gas used in the creation of the material. There is a class of insulation materials known as mass insulation. The measured insulation magnitude of mass insulation materials is referred to as an R-value. The R-value is dependent upon the thermal conductivity [W/(m-°K)] of the material and the pathlength that the heat traverses. (thermal energy). It is for this reason that the thickness of mass insulation is commonly treated or accepted as a linear function with respect to the material's R-value. The reason for this treatment or acceptance is due to the fact that very frequently heat traverses through mass insulation as a linear function of its thickness. Hence, R-value is a linear function of a material's thickness. The material structure description of the sheet 12 of the invention reveals that a more accurate classification for this insulation material is “absence of mass” insulation, which is due to the fact that its structure consists of a countless number of evacuated cells that are devoid of mass, namely elemental and molecular gases. The material is essentially comprised of randomized structures of the evacuated cells. Due to the cells' evacuated state, their thermal conductivity across the cell approaches the value of a vacuum, which is zero. The result is that each evacuated cell acts as a thermo-physical barrier to the conduction of heat through the material. This interrupts the natural directional flow of heat, and introduces a three-dimensional non-linear tortuous path in which the heat traverses through the material through the cell walls. It is important to realize that the tortuous path shown in the figures only illustrate a two-dimensional tortuous path when, in fact, it is actually a significantly more complex three-dimensional tortuous path. It is key to understand that the R-value for “absence of mass” insulation material is greatly enhanced by the length of the tortuous path traversed by the heat (thermal energy).

The house wrap 100 has a total thickness of generally less than 80 mils for the embodiment of FIGS. 3-4 and effectively always less than 175 mils for the embodiments of FIGS. 5-6. The house wrap 100 can be attached to a building in any conventional fashion, such as nail guns, or the like. The house wrap 100 has the flexibility and durability that is comparable to, and actually better than many, existing commercial house wraps. The house wrap 100 of the present invention can also be used as a roof paper or roof underlay.

The first, or front or drainage plane layer 40 is a reinforcing grid or mesh that functions as a drainage plane and will face the outside cladding. The mesh layer 40 can be formed effectively from polyethylene, however substantially any material providing the structural equivalent and suitable for the desired work environment could be used. The thickness of the mesh layer 40 and barrier layer 30 is, typically less than 10 mils, generally 8-9 mils. The mesh layer 40 can be formed effectively, into a wide variety of grid patterns, even a structural non-grid pattern as suggested again below.

The front layer 40 serves a drainage function by providing a space for water drainage. Secondly, the front layer 40 as well as the barrier layer 30 serves as a reinforcing member for the house wrap 100 to provide structural integrity to the entire assembly.

The front layer 40 could take other forms, such as spaced ribs or an elongated diamond pattern. Essentially the spaced ribs alternative design would be the mesh layer 40 without the cross bracing. The spaced ribs could be vertical or angled at essentially any angle to form more definitive drainage channels. A “vertical” orientation of such ribs would also allow the house wrap 100 to be easily rolled up in one direction (i.e. rolled about an axis parallel to the ribs). The ribs need not be straight members, but each rib could be a zig-zag, herringbone-shaped or diamond-shaped construction. The interconnected mesh layer 40 of the preferred embodiment is believed to add structural integrity while still allowing for an efficient drainage plane for the house wrap 100.

The second or middle or barrier film layer 30 is a breathable, non-perforated barrier film 30 which is bonded to the first layer 40 and together have a thickness of no greater than about 10 mils, generally 8-9 mils as noted. The second or middle layer 30 may be formed of a polyethylene (PE) or a Polyurethane (PUR) material, but a myriad of other breathable film layer materials could be used, assuming the cost concerns could be addressed, such as PVC film or polytetrafluoroethylene (PTFE) film. The PE or PUR materials are the most cost effective. In one embodiment, the film 30 is bonded to the layer 40 through thermal bonding. Other bonding techniques may be used, such as adhesives. The film layer 30 should have acceptable breathability for the field of house wraps.

Collectively, the film layer 30 and layer 40 may be tested or evaluated together for forming the house wrap 100. Collectively, the film layer 30 and layer 40 should exhibit an ASTM E-2273 (2016) test result of greater than 95%. ASTM E-2273 represents the standard test method for determining drainage efficiency of exterior insulation and finish system clad wall assemblies. Collectively, the film layer 30 and layer 40 should exhibit an air porosity (Gurley-Hill Air Porosity-TAPPI T-460 (2016)) of at least two thousand sec. Collectively, the film layer 30 and layer 40 should exhibit a water resistance of at least three hundred cm (AATCC-127 (2016).

The rear or foam layer 12 is a perforated expanded low density polyethylene foam 12 that is formed as noted above, and that is bonded to the middle layer 30, such as through nonwoven layer 50. The nonwoven layer 50 is the third layer.

The fourth or rear LDPE foam layer 12 is perforated, wherein a series of equally spaced perforations may extend through the layer 12. The perforations can be conical which may provide certain advantages to the house wrap 10 of the present invention. However, cylindrical shaped perforations would also be acceptable. The perforations can be formed on layer 12 through a perforation roller which has a series of perforation pins thereon. For the conical shaped perforations as shown, the pins would have a shape similar to the final desired shape of the perforations (with three holes per square inch being a preferred perforation density). The layer 12 can be perforated before it is assembled, which is the accepted perforation method, or the perforations can be made after the house wrap is assembled, which is less desirable.

The foam layer 12 should be about 1-1.1 millimeters (39-43 mils) in thickness, generally less than 45 mils, and always less than 75 mils for a conventional house wrap 100 of FIGS. 3-4. This design will provide insulation R-values of R-6 or greater.

The non-woven layer 50 of two to six mils thickness provides an improved bonding layer or adhesion promoting layer for the barrier film layer 30 and the foam layer 12, and yields improved stability and performance to the house wrap 100. Nonwoven layer 50 is formed from staple fibers, such as polyester fibers, bonded together by chemical, mechanical, thermal or solvent treatment. The non-woven layer 50 may be described as denoting a fabric which is neither woven nor knitted.

The FIGS. 3-4 show a house wrap 100 embodiment with a single layer of foam layer 12, however as noted above, multiple layers could be used as shown in the embodiment of FIG. 5. Hypothetically, a thick house wrap 100 up to ½ inch thick having multiple layers 12 exhibits an R-30 value. ASTM C-518 doesn't allow for multiple layers (>2 layers). An extended or thicker foam layer 12 of up to 2.5 millimeters (98 mils) can be formed using the process of the present invention and this is shown in FIG. 6 and represents an alternative method of achieving R-values up to R-15.

The foam 12 of the invention has other uses as well. Another particularly useful product is utilizing the LDPE foam in the construction of a composite fabric material as disclosed in U.S. Pat. No. 8,429,764, which is incorporated herein by reference.