DEVICES AND METHODS TO PROVIDE AIR CIRCULATION SPACE PROXIMATE TO INSULATION MATERIAL

Abstract

Devices and associated methods are provided for improving ventilation of insulation material and building construction and renovation. Specifically, the present disclosure includes devices and system(s) to achieve the ventilation of exterior walls and roofs. Components of the system(s) consider shut-down of the ventilation process when it is not necessary, such as in winter, and in the event of fire, where the prevention of vertical and horizontal fire spread is desired.

Description

The disclosure of each and every patent application referenced herein and above is incorporated by reference herein in its entirety for any purpose whatsoever.

COPYRIGHT NOTICE

A portion of the disclosure of this patent document contains material which is subject to copyright protection. The copyright owner has no objection to the reproduction by anyone of the patent document or patent disclosure as it appears in the Patent and Trademark Office, patent file or records, but otherwise reserves all copyrights whatsoever.

BACKGROUND

Field of the Disclosure

The present Disclosure Relates primarily to devices and system components for maintaining air circulation space proximate to thermal or other building insulation in order to facilitate the expulsion of heat and moisture from the insulation, such as in exterior walls and insulated roofs.

Description of Related Art

Thermal insulation is required in buildings to provide a barrier in the exterior envelope construction to the transfer of thermal energy from outside the envelope into the structure as in summer where mechanical energy is used to remove heat from inside the building envelope and in cold weather periods to reduce the heat energy loss from inside the building outward.

As the Governments of nations around the world increase the required resistance to prevent this transfer with periodic increases in the required thermal resistance of building envelope construction, other factors are also increased which must be mitigated. One of these is an ever-increasing need for the ventilation of framed, insulated spaces. Up to the present day, there has been little or no effort by the insulating industry to ventilate insulated, framed spaces.

Roof construction requires ventilation of super-heated air under roof sheathing to prevent deterioration of structures. This ventilation is provided for by the maintaining of an air space over thermal insulation. However, with ever-increasing thicker roof insulation required, and dimensional lumber having a nominal maximum depth of 12 inches, that space is impossible to maintain without a ventilating device to maintain a consistent air passage. The Insulation Industry has marketed a device for the last three decades that is designed to ventilate the roof below the roof sheathing, but by its nature excludes the fibrous insulation from the ventilation process.

Additionally, there has been no serious attempt to ventilate the thermal insulation un exterior framed walls. Fibrous building envelope insulating materials are dry when installed. They are rated for thermal resistance when they are dry, at perhaps 4% moisture content. From the moment the factory packaging is opened for the installation into framed wall cavities, they begin to absorb moisture with the resulting decrease in the thermal resistance rating—“R”. It is believed by Applicant that most thermal insulation in tight buildings with no water influx problems is generally deteriorated to about half of its original R value after only a year or two in most climates, and that there is less deterioration in dry climes and greater deterioration in humid areas such as in the southeastern U.S. and along coastal shores and near bodies of water. Applicant further believes that this is because the absorbent fibrous insulation assumes some of the ambient moisture prevalent in its locale. Other factors influence the amount of acquired moisture a building structure and its thermal insulation absorbs. The kind of heating system influences the moisture, as well as the habits of a building's occupants, such as cooking involving unusual amounts of boiling water, hot, steamy showers and the frequency and number of occupants doing same. In addition to the aforementioned, leaks permitting water infiltration through the outer skin of the structure into the building frame and insulation such as due to roof and flashing leaks, poorly installed doors, windows, and building wrap and dried and cracked caulking and siding is not uncommon. Additionally, most structures are framed in wood, a renewable material. Out of necessity and because of exorbitant energy costs to kiln dry lumber, most framing is built from green lumber of species which are fast-growing and including significant moisture. The speed which most buildings are built at only allow weeks of drying time where the green lumber is nailed in place and allowed to lose some of its internal moisture instead of, ideally, six months or more in the view of Applicant. The frames are enclosed and insulated and then sealed with wall board. This wet wood then expels its extra moisture directly into the adjacent insulation providing a “jump-start” to a life of deterioration of the “R” value of the insulation.

This retention of moisture not only results in a major consumption of fossil fuels, depleting resources and potentially adding to such climatic issues such as global warming, but adds to the cost of owning, heating and cooling structures. In more extreme examples, mold supported by excessive moisture can cause respiratory distress and even death due to toxins, for example, by created by fungus growing on the mold.

While roof insulation is not currently directly ventilated, because of its much higher ambient operating temperatures, it probably does expel some acquired moisture because some of the moisture is forced from roof framing cavities as steam under pressure. No such ventilation exists for wall assemblies and ambient temperatures are lower in walls, likely resulting in little or no expulsion of accumulated water as steam. It is in exterior walls where moisture levels are greatest, particularly in the lower portions of walls. Moreover, the present use of baffles encourages horizontal fire spread as unrestricted vents in roof soffits provide fresh air that may feed fire spread in roofs. Currently, no industry attempts have been made to ventilate exterior walls.

SUMMARY OF ASPECTS OF THE DISCLOSURE

The present disclosure includes devices and system(s) to achieve the ventilation of exterior walls and roofs. Components of the system(s) consider shut-down of the ventilation process when it is not necessary, such as in winter, and in the event of fire, where the prevention of vertical and horizontal fire spread is desired. The present disclosure provides for control of air flow in the event of fire, among other things.

In one embodiment, a method of retrofitting a building structure is provided, including removing external sheathing from a plurality of vertically-oriented studs forming an external wall of a building, applying extension strips along the length of an outwardly-facing surface of each stud, and applying sheathing to the extension strips. If desired, the method can further include applying a spacer device to an inner surface of the sheathing between adjacent studs having a body that permits moisture to therethrough, and disposing insulation material proximate the spacer device, wherein the spacer device defines a vertically-oriented ventilation channel between the building sheathing and the insulation material, wherein the spacer body permits moisture to be passed from the insulation material to the ventilation channel.

In accordance with a further aspect, the method can include applying cross bracing to the studs and/or the extension strips. The method can also include constructing a horizontally-oriented air plenum proximate a lower portion of the building in fluid communication with a plurality of vertically-oriented ventilation channels disposed between the building sheathing and insulation material. The plenum is equal to or shorter than the horizontal length of the building where the plenum is located. Preferably, the plenum is less than about twenty feet long, and is located proximate a floor platform of the building. The method can also include disposing an air intake vent in fluid communication with the plenum. Preferably, the air intake vent can be selectively closed and opened. At least some of the studs are made from metal and/or wood. If desired, the method can further include disposing an active fire stop device between adjacent studs to permit vertical airflow in the space defined by the spacer device when the fire stop is in an open condition, and that prohibits vertical airflow when the fire stop is an a closed condition.

In accordance with another aspect, a method of retrofitting a building structure is provided, including removing external sheathing from a plurality of rafters forming a roof surface of a building, applying extension strips along the length of an outwardly-facing surface of each rafter, and applying sheathing to the extension strips. If desired, the method can further include applying a spacer device to an inner surface of the sheathing between adjacent rafters having a body that permits moisture to therethrough, and disposing insulation material proximate the spacer device, wherein the spacer device defines a ventilation channel parallel to the rafters between the building sheathing and the insulation material, wherein the spacer body permits moisture to be passed from the insulation material to the ventilation channel. In accordance with a further aspect, at least some of the rafters can be made from metal and/or wood.

The accompanying drawings, which are incorporated in and constitute part of this specification, are included to illustrate and provide a further understanding of the methods and systems of the disclosed embodiments. Together with the description, the drawings serve to explain principles of the disclosed embodiments.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a schematic diagram of an exemplary low voltage control system in accordance with the disclosure.

FIG. 2 is an illustration of a first exemplary framing technique in accordance with the disclosure.

FIG. 3 is a partial wall section of FIG. 5.

FIG. 4 is a second partial wall section of FIG. 5.

FIG. 5 is an illustration of a second exemplary framing technique in accordance with the disclosure.

FIG. 6 is a third partial wall section of FIG. 5.

FIG. 7 is a fourth partial wall section of FIG. 5.

FIG. 8 is an exemplary spacer device provided in accordance with the present disclosure.

FIG. 9 is a cross section of a portion of a spacer device provided in accordance with the present disclosure.

FIG. 10 is a longitudinal section through the spacer device of FIG. 8 showing an exemplary installation condition.

FIG. 11 is a further section through the spacer device of FIG. 8.

FIG. 12 is an exemplary ventilation device attached to sheathing and fabric added for blown-in insulation in accordance with the disclosure.

FIG. 13 is a second exemplary spacer device provided in accordance with the present disclosure.

FIG. 14 is a horizontal section through a framed wall with building sheathing attached having foamed-in-place polyiso or other such insulation and a first exemplary ventilation device in accordance with the disclosure as shown in FIG. 15.

FIG. 15 is an isometric view of an exemplary ventilation device intended for use with spray-in expanding foam plastic insulation or similar material.

FIG. 16 is a horizontal section through a framed wall with building sheathing attached having foamed-in-place polyiso or other plastic insulation and a second exemplary ventilation device in accordance with the disclosure.

FIG. 17 is a section through a preformed, or formed-in-place portion of a ventilation device in accordance with the disclosure.

FIG. 18 is an isometric view of a ventilation device for spray-in foam insulation pre-formed for specific stud spacing folded to fit a framing bay.

FIG. 19 illustrates a framed wall space with stud framing on 16″ centers including a fire stop device.

FIG. 20 illustrates a framed wall space with stud framing on 16″ centers including a plurality of fire stop devices.

FIG. 21 is an isometric view of a first embodiment of a fire stop in accordance with the disclosure.

FIGS. 22-25 are various views of the fire stop of FIG. 21.

FIG. 26 is an isometric view of a second embodiment of a fire stop in accordance with the disclosure.

FIGS. 27-30 are various views of the fire stop of FIG. 26.

FIGS. 31-35 are various views of an air shutter provided in accordance with the disclosure.

FIGS. 36-39 are various building constructions using devices and techniques provided in accordance with the disclosure.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Reference will now be made in detail to the present preferred embodiments of the disclosure, examples of which are illustrated in the accompanying drawings. The method and corresponding steps of the disclosed embodiments will be described in conjunction with the detailed description of the system.

For purposes of illustration, and not limitation, FIG. 1 is a schematic diagram of an exemplary low voltage control system to control air intake to insulated framing bays. A temperature sensor switch 201 is illustrated which can be located on a roof soffit protected from the elements and direct sunlight. It is preferable to shut-off power to the intake solenoids, 202, when ambient outside temperatures drop below a preset temperature such as 40 degrees F. Closing the cavities to cold air is desirable as cold air is naturally dry, and a static air space would add to the insulating values of the exterior wall assemblies. 203 indicates a central low voltage control unit which ties the intake solenoids with the smoke and fire detection alarm system. When a smoke or fire detector is triggered, power is turned-off to the solenoid valves. Additionally, if there is a power interruption to the structure, the ventilation system is shut-down.

A plurality of smoke and (or) fire detectors 204 can be provided. The solenoid intake valves are preferably equipped with diagnostic lights to allow the visual inspection of the system. Two LED elements, such as red and green, can be used. Accordingly, if the green light glows when the intake shutters are supposed to be open, it will be apparent that the shutter is working properly. If the shutter is supposed to be closed, such as in cold weather, or when a fire alarm test is being performed, the observer will note proper operation. If neither light is on, or not in the right color further investigation will be apparent to the occupant of the structure.

For purposes of further illustration, and not limitation, FIG. 2 is an illustration of the framing of a new building framed of wood, utilizing the projecting stud framing method to create a continuous vertical ventilation channel between each wall stud and extending vertically from the foundation to the roof soffit. 196 refers to a foundation wall, and a thermostatic control 201 is provided in the roof soffit to control the shutter solenoids in cold weather. Wall framing studs 205 are provided which are typically spaced at 16 inches on center. Spacings of 12 inches and 20 or 24″ can also used but are far less common. The structure further includes roof rafters 209 which may or may not be insulated, as desired. An air space 206 is defined by the use of the projected framing method. If nominal 2×4 inch top and bottom wall plates are used with nominal 2×6 inch wood studs, the depth of the air passage by-passing floor structures 197 and 198 and top plate 199 will be approximately 2 inches. Framed openings 195 are further defined in the exterior wall as required for windows and doors. Filler strips 207 are also provided, preferably being approximately 2 inches thick and are used to fill-in between studs to form discrete air channels at floor structure 198 and top plate supporting roof framing 199 and at the inlet distribution plenum 208 which is adjacent to floor structure 197. Vertical strips divide the plenum into horizontal lengths consistent with various Fire Code requirements.

Filler strips 207 may be of cut-down dimensional lumber or pre-formed strips made from composites such as “Homasote” material, a material made from recycled paper fibers by the Homasote Company (West Trenton, N.J.). At the plenum, a horizontal bottom closure of the same strips contain the solenoid controlled intake shutters, 202 which are ideally located near the center of each plenum space. Under typical present building requirements, horizontal spaces must be fire stopped every 20 linear feet. It therefore follows that the air intake plenums will have a suitable similar length. Active fire stops 211 are provided, located at floor and plate lines in order to prevent vertical fire spread. These fire stops 211 preferably incorporate an intumescent material that expands at temperatures of 300 degrees F., which can be expected to be reached if fire enters the framed space. The air gaps of the fire stops are thus closed preventing or mitigating the vertical spread of fire. In the event that the smoke or fire detection system is activated, or ambient exterior temperatures drop below a certain temperature, the solenoid-controlled intake shutters 202 are adapted to close to prevent the entrance of outside air into wall cavities.

For purposes of further illustration, and not limitation, FIG. 3 illustrates a partial wall section at the location shown on FIG. 5. It illustrates the lower part of a framed wall formed with projecting wall studs 196 again refers to the foundation wall and 197 indicates the first floor structure. Arrows show the direction of air flow from the outside, through the solenoid controlled intake shutter, 202 and into the air plenum, 208 where incoming air is distributed horizontally to individual stud 205 bays which are insulated with fibrous insulation. The air passage is ensured by the ventilation device, 215. The section illustrates the foundation outer surface and floor framing in one line and the projecting studs extending out approximately 2 inches to create the ventilation channel. FIG. 4 illustrates the upper portion of the same wall structure. Specifically, FIG. 4 illustrates the second floor structure and top plate flush with the wall studs 205 on the inside face and set back on the outside face to provide a ventilation space insured by the preferred ventilation device, 215. Active fire stops incorporating intumescent material are shown attached to the floor framing 198 and top plate, 199. Fibrous wall insulation 213 is provided, as well as roof insulation 214, where the underside of the roof has conditioned space.

As illustrated, the ventilation device 215 maintains a ventilation space below the roof sheathing allowing superheated air to be ventilated out to a ventilation attic or roof vent system and also prove positive ventilation of heat and moisture from the roof insulation. Note that the roof soffit 216 is not ventilated as is presently done. In one embodiment, the roof eave assembly is caulked tight to ensure a positive flow up through the wall cavities and over the roof insulation and improves the present condition wherein horizontal fire spread is facilitated because of the use of unrestricted soffit vents.

For purposes of further illustration, and not limitation, FIG. 5 illustrates a portion of a 2 story framed wall in an existing building or a framing system employing metal studs. The existing studs or metal studs are not projecting to create vertical ventilation channels. The channels can be formed by applied filler strips 207 about 2″ thick made from ripped-down two inch nominal framing lumber or pre-molded strips of composite material such as “Homasote” material. Wall bracing is preferably achieved using galvanized metal “X” bracing (i.e., cross-bracing), 210 of perforated or pre-drilled strapping of approximately 12 gauge by 2 inches wide. Where new or existing metal framing is used, the frame is plumbed, and the “X” bracing can be installed with screws or fillet welded. The filler strips are then preferably attached to the faces of studs and continuous from lowest floor platform 197 to top plate, 199. Where an existing building is being retro-fitted with the insulation ventilation system as disclosed herein, “X” bracing is preferably installed sequentially as existing sheathing is removed in order to maintain building plumb and bracing at all times. 195 illustrates framed openings, 196 indicates the foundation wall, 197 is the first floor platform, 198, the second floor platform and 199 is the top plate. The active fire stops are 211.

For purposes of further illustration, and not limitation, FIG. 6 is a partial section through the lower portion of an exterior wall shown in FIG. 5. It indicates a framed wall without projecting studs as in normal construction. The ventilation channels at stud bays are formed by adding filler strips 207 to all studs 205 and run continuously over bottom plate (sill), box ends and end joists at each floor (197, 198) level and top plate 199. 196 refers to the foundation, 202 indicates a solenoid controlled inlet shutter set into openings in a horizontally installed length of filler strip that supports the lower projection of the building wall sheathing and encloses the air distribution plenum 208 at its bottom edge. 210 indicates exemplary steel “X” strapping attached to the face of wood or metal framing 205. The filler strips 207 creating the vertical ventilation channels are then attached over the strapping 210 to the faces of the studs and other framers. The sheathing, which is preferably exterior plywood but may be other kinds of sheathing such as exterior gypsum sheathing is preferably attached to the filler strips 217 with long screws extending through the filler strips and into the wood or metal studs. The filler strips may be tacked to the framing, for example, with screws or a self adhesive backing to facilitate their installation and that of the sheathing. The insulation ventilation device is indicated by 215.

For purposes of further illustration, and not limitation, FIG. 7 is a partial section through the upper portion of an exterior wall shown in FIG. 5. It is the upper part of the wall section illustrated in FIG. 6. 215 represents an exemplary insulation ventilation device shown between wall 213 roof 214 insulation and wall and roof sheathing. 211 depicts an active fire stop using intumescent strips. 216 indicates the soffit and fascia construction which is preferably assembled tight and caulked to insure a positive gravity air flow and maximum control over air entry by the solenoid controlled inlet valves to mitigate fire spread. 210 indicates preferably galvanized steel “X” bracing.

For purposes of further illustration, and not limitation, FIG. 8 illustrates a preferred example of a ventilation device. It may be molded of a plastic having good memory and capable of maintaining its shape at temperatures of at least 275 degrees F. 250 indicates the spacer struts which are about ⅝″ long, but testing may result in a shorter or longer strut being used. 251 indicates the open backing of a gridwork of the same plastic and molded integrally with the struts. Deepened lateral ribs 252 insure greater stiffness in the width of the device to make handling and installation easier. Occasional deepened ribs may be used to aid in handling. In this illustration such a deepened rib is presented in every third row. Longitudinal ribs are preferably shallower to permit rolling up of the device for packaging and storage. 253 is a break-away panel which can be used for attachment to sheathing by stapler. It may contain trademark, indicia, or other product information.

For purposes of further illustration, and not limitation, FIG. 9 illustrates an example of a suitable shape of the cross-section through a deepened lateral rib of the ventilation device shown in FIG. 8. 252 indicates the deepened portion and 258 indicates an occasional appendage designed to embed hooks into a filter fabric which would be employed for blown-in fibrous insulation to contain the small particulates of this kind of insulation.

For purposes of further illustration, and not limitation, FIG. 10 is a longitudinal section through the ventilation device in FIG. 8 showing the typical condition and cutting through the lateral grid members. 250 indicates spacer struts spaced approximately an inch apart in both directions and approximately ⅝″ long. The plastic or other material used in this embodiment of the ventilation device is preferably flexible, with excellent memory and moderately high temperature operating range. The struts, 250, ideally will be able to be bent parallel to the plane of the grid body 251 to permit rolling-up for compact storage and handling. 253 is an exemplary occasional fabric attachment appendage. 255 represents fibrous thermal insulation.

For purposes of further illustration, and not limitation, FIG. 11 illustrates a similar longitudinal section as in FIG. 10, but through one of the occasional break away panels 253. 250 indicates spacer struts, 251, the gridwork, 255, fibrous insulation blankets and 253 the solid break away panel that has weak connections on the two long sides and one end. The other short end is preferably thin and flexible and acts as a hinge. A second weak, flexible line can be provided within the solid panel to provide a second fold for the panel to facilitate attachment to building sheathing.

For purposes of still further illustration, and not limitation, FIG. 12 shows an exemplary ventilation device attached to sheathing and fabric added for blown-in insulation. 256 indicates the building sheathing, 250, the spacing struts, 251, the grid backing, 256, the fabric attachment, 255 the insulation which would be blown-in and 253 shows the attachment panel broken out of the grid backing 251 and stapled to the inside face of the sheathing. 257 points to broken lines indicating a stapling gun. FIG. 13 is an isometric view of another preferred embodiment of a device for ventilating fibrous insulation. It incorporates a solid backing 251, which is perforated 258, with integral spacer struts 250, and may have integral lateral stiffener bars, 252. The backing 251 may have occasional panels that have weak connectors on three sides and thin fold area on one side as one located within the panel to facilitate the attachment to the back face of building sheathing as in the previous embodiment. The perforations 258 may be more numerous and smaller in size for use with blown-in fibrous insulation.

For purposes of yet further illustration, and not limitation, FIG. 14 is a horizontal section through a framed wall with building sheathing attached. The wall is insulated with sprayed-in poly iso or other formulation of rigid insulation. An exemplary ventilation device is shown and indicated as 259. The ventilation device preferably has a solid backing and creates an air space between the wood framing, sheathing and foam insulation, 261. This is to permit trapped moisture of green framing lumber (or from other sources, such as a roofing leak) to gradually be convected to the atmosphere through frame leakage such as joints in plywood, and lapped building wrap. When liquid expanding foams are sprayed against wood framing and sheathing, the pre-expanded liquid binds with the surface of wood and provides a permanent seal locking in the wood's moisture and providing a medium for organic growth that can result in rot of the structure. Ventilation devices and associated techniques are provided to prevent this. Device 259 is preferably turned at the top and bottom of each cavity to protect the top and bottom plates.

As further depicted in FIG. 14, to enhance the escape of trapped moisture, a wicking pad 269 can be provided between each stud face and sheathing to encourage moisture to wick away from wet lumber and into the ventilation channel defined by the ventilation device 259. Wicking pads are preferably made from “Homasote” material that is preferably not treated for water repellency of suitable thickness (e.g., ½ inch) and width (e.g. 1.5 inches) and length (e.g., the length of the stud). The illustrated spandrel strips 270 can also be provided, for example, proximate the edge of each building platform (e.g., floor joist outer faces and box ends at floor plates such as 3660, 3670 depicted in FIG. 36 if foam insulation is used in lieu of fiberglass or cellulose insulation) between floors and at the top plate (such as at a second floor/attic interface) to provide vertically-oriented grooves to permit moisture to travel from floor to floor up through the ceiling plate into an attic space and eventually out of a ridge vent or other vent.

By way of further illustration, and not limitation, FIG. 15 is an isometric view of an exemplary ventilation device intended for use with spray-in expanding foam plastic insulation as shown in FIG. 14. This embodiment preferably maintains a separation of approximately ¼″ between the wood framing, sheathing and the insulation. The device has spacing struts 260, which are approximately ¼″ long and about an inch apart in either direction in the plane of the ventilation device. As with the other ventilation devices, the tips of the struts contact the sheathing but also the framers. 261 points to the solid backing, 262 is an exemplary attachment area where staples may be applied for attachment to wood framing. Additionally, occasional staples may be applied through the device into the sheathing for attachment. Lines 263 are weakened folds for 16″ on center stud spacing. Lines 264 are weakened fold lines for 12″ stud spacing, Lines 265 are weakened fold lines for flexing to permit the attachment areas to sit squarely against wood framers for stapling.

For purposes of further illustration, and not limitation, FIG. 16 is a horizontal section through a framed wall with building sheathing attached. The wall cavity is insulated with sprayed-in poly iso or other formulation of rigid insulation. An exemplary ventilation device is shown, 266 made from entangled net technology as manufactured by Colbond, Inc. U.S. Pat. No. 4,212,692 discloses a method of forming the “entangled net” material, which is incorporated by reference herein in its entirety. The thickness of device 266 is preferably about ¼″. 261 indicates the foam insulation. 267 indicates an impervious membrane, such as polyethylene film. Attachment of the film may be made by stapler at any location, or be pre-attached during manufacture. 269 indicates wicking pads attached to studs between stud faces and sheathing to provide a path for escaping moisture. 270 indicates the grooved spandrel strips that will provide channels for air movement.

For purposes of further illustration, and not limitation, FIG. 17 is a section through a preformed, or formed-in-place portion of this embodiment of ventilation device for foamed-in-place insulation in wood construction. 266 is the body of the preferred device approximately ¼″ thick. 267 is an impervious membrane such as polyethylene. The foam is sprayed against the membrane attached to the installed device fabricated of Entangled Net technology as described in other patent applications incorporated by reference herein. FIG. 18 is an isometric view of a ventilation device for spray-in foam insulation pre-formed for specific stud spacing folded to fit a framing bay. 266 is the body of the preferred ventilation device. It is pre-folded to fit common framing centers, or folded in place. 267 is an impermeable membrane which may be pre-attached to the device, or it may be attached after, but prior to application of the insulation. It must act as a separator between the device and the foam application. FIG. 19 illustrates a framed wall space with stud framing on 16″ centers, which is the most commonly used spacing. 402 indicates a 16 inch dimension to the center of the wall framing studs. 400 indicates a pre-molded active fire stop which is slightly longer than the space is wide. Tight end closure is obtained by rotation until the fire stop jambs at the ends. The fire stop body must be as air tight as possible to be most effective.

For purposes of still further illustration, and not limitation, FIG. 20 illustrates a framed wall space with stud framing on 12″ centers. This spacing is less common than 16″ and a spacing less than 16″ might be more commonly encountered where dimensions of a wall result in some bays having lesser dimensions. 403 indicates a 12″ or otherwise less than 16″ dimension for studs. 400 indicates a fire stop for 16″ spacing used with a greater skew to fit into a smaller space. 401 indicates a shorter active fire stop unit which might be available if it were found that there was a sufficient market to warrant a manufacture of a shorter device.

FIG. 21 is an isometric view of a preferred embodiment of an active fire stop using internal springs to maintain a seal between the floor or plate framing line and the building sheathing. The bottom half 404, of the molded plastic or composite fire stop preferably snaps into the upper half, 405 after intumescent material 409 is applied with adhesive or a self-adhesive backing to the flat portions forming the upper and lower ventilating surfaces. 404 is the curved end that is jammed against the wood framing or filler strip stud extensions to maintain a tight seal. 405 indicates the top face of the fire stop. It is preferably pushed-in by the sheathing as the sheathing is installed. As this happens, the assembly is compressed along with the internal springs for an optimal seal. 407 indicates tabs for nailing the fire stop to the building framing. The top surface has an indentation to accommodate a portion of foam backer rod if necessary to improve the seal.

By way of further example, FIG. 22 is a longitudinal vertical section (C-C) through a preferred device using internal springs to maintain a seal between sheathing and framing as is shown in FIG. 21. It shows how 404, the bottom half snaps into 405, the top half. 406 indicates the compression springs which are preferably protected against corrosion. 404 and 405 are ideally molded from a plastic or composite that has a moderately high heat resistance over 350 degrees F. 409 indicates the applied intumescent strips which expand approximately 20 times their thickness when exposed to the heat of a fire, at about 300 degrees F. 407 indicates the attachment tabs. The dashed line on top of 405 indicates a possible length of foam backer rod to improve the seal if necessary. FIG. 23 is a lateral vertical section through the active fire stop through A-A. It illustrates how 404, the bottom half snaps into the top half 405. 406 indicates one of the compression springs. FIG. 24 is a view of the top of a fire stop as shown in FIG. 21. Springs 406 are located each end and a central spring if required. 407 indicates the attachment tabs. FIG. 25 is a lateral vertical section B-B, through the controlled air passages. 404 is the bottom half, 405 is the top half. 406 indicates a compression spring and 407, the attachment tab. 409 indicates the intumescent strips attached to the top and bottom air passage surfaces.

For purposes of further illustration, and not limitation, FIG. 26 is an isometric view of another embodiment of a preferred active fire stop utilizing intumescent strips. Unlike the previous embodiment, the top and bottom seal is not maintained by compression springs. This version maintains the seal by compressing a finned top 410 form that is integral with the upper casting 405. 409 indicates the intumescent strips. 407 shows the attachment tabs. FIG. 27 is a longitudinal vertical section (C-C) of the preferred embodiment in FIGS. 26. 404 and 405 are the bottom and top halves which are snapped together after the intumescent strips 409 are applied to the upper and lower surfaces of the air passage slot. 407 indicates the attachment tab and 410 is the integral top fin which compresses against the building sheathing as it is applied to the framing. FIG. 28 is a transverse vertical section (A-A) of the ventilation device in FIGS. 27. 404 and 405 are the bottom and top halves. The top half 405 has the compression fins 410 at its upper portion. 407 indicates the attachment tabs.

FIG. 29 is a plan view of the previous device. 407 indicates the attachment tabs and 410 the compression fins to maintain an air seal. FIG. 30 is a transverse vertical section (B-B) through the ventilation slot of the previous device. 404 and 405 are the bottom and top halves. The top half includes the compression fins 410. The bottom half includes the attachment tabs 407.

For purposes of further illustration, and not limitation, FIG. 31 is an isometric view of a solenoid-controlled air shutter which is also referred-to as 202 in FIG. 1. The view is of the device turned up-side-down, showing a view of the bottom side. 300 is the housing of the shutter preferably molded of plastic, composites or formed from aluminum. 304 is a debris screen to catch particulates loosened by air movement which might jam movement of the shutter. Occasional cleaning of this screen may be appropriate. 305 is an insect screen to prevent insects from entering the ventilation space. 307 indicates the shutter air openings. 308 and 309 are red and green indicator lights or other colors as desired. They indicate whether the shutter is open or closed. Green would indicate “open” and red might indicate “closed. In normal operation all of the air inlet shutters should be the same color, or no light at all. A typical residence might require a minimum of 6 shutters. 310 indicates a hole for attachment at the bottom of the plenum. 311 is a gasket, if necessary to enhance the air seal. It might be of self-adhesive foam tape or other compressible material. 312 indicates the signal and power cable to link the shutters to the low voltage temperature sensing and fire protection system.

For purposes of further illustration, and not limitation, FIG. 32 is an isometric view of the solenoid-controlled air shutter described in FIG. 31. It is shown in the position as it is used. This view permits observation of the activating mechanism. 300 is the housing that encloses the electro-magnetic solenoid 301 which is electrically energized when the shutter is open allowing air into the system. Unlike most solenoid coils, it is designed to remain on constantly without creating excessive heat or power consumption. A return spring closes the shutter if there is a fire, if the temperature drops below a selected temperature, or if there is a power failure. 302 is a non-magnetic rod connecting the moving iron coil core with the shutter mechanism 303. 304 is the debris screen. 305 is the insect screen. 310 indicates a screw hole for attachment. 311 is a gasket, if necessary to improve the air seal. 312 points to the signal and power cable.

For purposes of further illustration, and not limitation, FIG. 33 is a vertical longitudinal section through the preferred air intake shutter as described in FIGS. 31 and 32. 300 is the housing containing the solenoid, shutter and return spring. 301 indicates the electromagnetic coil of copper wire wound on a non-metallic bobbin with an iron housing. A moving iron core has a non-magnetic rod 302 linking the core to the moving part of the shutter 303. A return spring 306 closes the shutter when power to the coil is discontinued. 304 is the debris screen and 305 is the insect screen. 307 are the air inlet holes of non-moving part (housing 300) of the shutter. 308 and 309 are the LED elements to aid in diagnostics. 310 indicates exemplary attachment screw holes.

FIG. 34 is a bottom view of the air inlet shutter. 300 is the housing which includes flange ears at each end for attachment to the building. 305 an the insect screen. The air inlet holes 307 are part of the housing 300. 308 and 309 are the diagnostic lights and 310 are holes for attachment to the horizontal closure strip of the air distribution plenum. FIG. 35 is a transverse vertical section through the air shutter described in FIGS. 32, 33 and 34. It is shown installed at the bottom of the air distribution plenum portion of a ventilated exterior wall. 300 is the housing 301 is the solenoid coil. 304 indicates the debris screen to prevent particulates from the insulation and framing from jamming the mechanism. 305 indicates the insect screen.

FIGS. 36-39 provide further illustration of how devices and techniques described herein can be employed in various types of building structures.

For example, FIG. 36 illustrates a wall-roof assembly with a cathedral ceiling, for example, with two inch by six inch nominal dimensional lumber studs 3645 that project outwardly beyond four inch nominal base plates to create vertical channels outside the second floor platform 3660. Preferably, filler strips 3635 are used to make the channels continuous. The structure further includes a first floor platform 3670 and insulated rafters 3615 tied to one another, for example, by a collar beam 3625. Ventilation spacers 3640 are provided in the wall and cathedral ceiling/roof structures. While fiberglass or cellulose insulation would also be included in locations designated 3620, it is not illustrated in this drawing to facilitate illustration of other components of the system. In addition, active firestops 3630 are also provided to control fire spread in the event of a building fire at the second floor platform 3660 and proximate the top plate 3650. In operation, ventilation air is taken into the structure at air intake shutter 3695 at the base of the building proximate foundation 3690. An air intake plenum is defined in the space between the sheathing and the first floor platform 3670 that spans a desired horizontal distance along the wall structure of the building. As illustrated, a filler strip 3635 can be provided along the first floor platform 3670 that limits the length of the plenum 3680. Each plenum can be, for example, less than twenty feet in length under present fire code regulations, wherein each plenum 3680 has a dedicated air intake shutter 3695, whereby each plenum is in fluid communication with the spacer devices 3640 and the portion of the ridge vent 3610 that are above it. As such, when shutter 3695 is open, air can enter plenum, and proceed, for example, by natural convection, up through the vertical channels defined by pairs of studs 3645 to the ridge vent 3610, removing moisture from the insulation. In the event of fire, the firestops and shutter close to reduce the spread of fire.

By way of further example, FIG. 37 illustrates a retrofitted wall-roof assembly similar to FIG. 36 with an attic space 3710, but preferably an existing structure that is originally made from two inch by four inch nominal dimensional studs and then retrofitted to include two inch square nominal dimensional stud extensions 3745 along the studs and past the second floor platform 3760. Preferably, “X” bracing straps 3735 are applied to the structure as existing sheathing is removed during the retrofitting procedure. Ventilation spacers 3740 are provided in the wall and roof structures. As with the embodiment of FIG. 36, while fiberglass or cellulose insulation would also be included in locations designated 3720, it is not illustrated in FIG. 37 to facilitate illustration of other components of the disclosed system. An addition, active firestops 3730 are also provided to control fire spread in the event of a building fire at the second floor platform 3760 and proximate the top plate 3750. In operation, ventilation air is taken into the structure at an air intake shutter (not shown) or similar structure at the base of the building proximate foundation 3790. An air intake plenum 3780 is defined in the space between the sheathing and the first floor platform 3770 that spans a desired horizontal distance along the wall structure of the building. As with the embodiment of FIG. 36, each plenum can be, for example, between eight and sixteen feet long, wherein each plenum 3780 is in fluid communication with the spacer devices 3740 and the portion of the ridge vent that are above it. Operation of the ventilation flowpaths and firestops is the same as described with respect to FIG. 36. It will be further appreciated that the above-described retrofitting procedure can equally be applied to a building with metal framing.

FIG. 38 illustrates a building structure similar to FIG. 36, but having an unfinished or ventilation attic 3810 in lieu of a cathedral ceiling. Thus, as with FIG. 36, two by six inch nominal studs 3845 are used projecting beyond four inch wide base plates and past the second floor platform 3860. Stud filler strips 3735 are applied to the edge of the second floor platform 3860 as well as to the first floor platform 3870 to limit the length of air intake plenum 3880. Ventilation spacers 3840 are provided in the wall and roof structures. As with the embodiment of FIG. 36, while fiberglass or cellulose insulation would also be included in locations designated 3820, it is not illustrated in FIG. 38 to facilitate illustration of other components of the disclosed system. An addition, active firestops 3830 are also provided to control fire spread in the event of a building fire at the second floor platform 3860 and proximate the top plate 3850. As with the preceding two embodiments, ventilation air is taken into the structure at an air intake shutter (not shown) or similar structure at the base of the building proximate foundation 3890 into air intake plenum 3880. Operation of the ventilation flowpaths and firestops is the same as described with respect to FIGS. 36-37.

FIG. 39 illustrates a building structure similar to FIG. 38 having an unfinished or ventilation attic 3910, but being made from metal framing. Two by four inch metal framing is depicted having vertical extensions 3945 can be, for example, two inch nominal cross sectional diameter wood, or a fibrous material such as “Homasote” material of any desired thickness (e.g., 0.25 inches thick or greater). Extension strips 3945 are used to project beyond the four inch wide base metal framing and past the second floor platform 3960 as well as selectively to the first floor platform 3970 to limit the length of air intake plenum 3980. “X” bracing strips 3935 are provided to brace the structure. Ventilation spacers 3940 are provided in the wall and roof structures. As with the embodiments of FIGS. 36-38, while fiberglass or cellulose insulation would also be included in locations designated 3920 including between the ceiling joists proximate the attic space 3910, it is not illustrated in FIG. 39 to facilitate illustration of other components of the disclosed system. An addition, active firestops 3930 are also provided to control fire spread in the event of a building fire at the second floor platform 3960 and proximate the top plate 3950. As with the preceding three embodiments, ventilation air is taken into the structure at an air intake shutter (not shown) or similar structure at the base of the building proximate foundation 3990 into air intake plenum 3980. Operation of the ventilation flowpaths and firestops is the same as described with respect to FIGS. 36-39.

It will be further appreciated that the structures of FIGS. 36-39 can be modified as disclosed herein to use spray foam insulation using techniques, for example, described herein with respect to FIG. 14, whereby wicking members can be provided outside of 2 by four inch framing, and spandrel pieces can be provided underneath the sheathing along the first floor platforms, second floor platforms and the platform that separates the second floor from the attic.

The methods and systems of the present invention, as described above and shown in the drawings, provide for insulation and associated systems with superior properties to those of the prior art. It will be apparent to those skilled in the art that various modifications and variations can be made in the devices and methods of the disclosed embodiments without departing from the spirit or scope of the disclosure. Thus, it is intended that the present disclosure include modifications and variations that are within the scope of the subject disclosure and equivalents.

Claims

1. A method of building a structure, comprising: a) erecting a frame from at least one of studs and rafters, and sheathing the frame with sheathing, wherein at least one of the studs, rafters and sheathing is made at least in part from a wood product;b) installing a spacer device between the portion of the frame and sheathing made at least in part form a wood product to at least partially cover said portion of the frame and sheathing made at least in part form a wood product;c) spraying foam insulation over the spacer device and said portion of the frame and sheathing made at least in part from a wood product to define a ventilation channel between the spacer device and said portion of the frame and sheathing made at least in part from a wood product to permit trapped moisture of wet lumber to be transported to the atmosphere.

2. The method of claim 1, wherein the spacer device is installed in a wall cavity to define an air space between the spacer device and a portion of the structure defining the wall cavity to permit trapped moisture of wet lumber to be transported to the atmosphere.

3. The method of claim 1, further comprising disposing a wicking pad between a stud face or rafter face and adjacent sheathing to cause moisture to wick away from the stud face, rafter face or adjacent sheathing wet lumber and into the ventilation channel.

4. The method of claim 1, wherein the spacer device maintains a separation of about one quarter of an inch between the insulation and said portion of the frame and sheathing made at least in part from a wood product.

5. The method of claim 1, wherein the spacer device has spacing struts that are spaced apart in a spaced apart pattern on in a plane of the ventilation device.

6. The method of claim 1, wherein the spacer device includes a solid backing.

7. The method of claim 1, further comprising fastening the spacer device to wood framing using at least one fastener in a designated attachment area.

8. The method of claim 1, wherein the spacer device is made from a sheet of material having lines of weakness to permit the spacer to fold to permit the spacer device to sit squarely in corners of a framing bay prior to being sprayed with insulation.

9. A method of constructing a building comprising: a) constructing a wall structure from a plurality of vertically-oriented studs to form an external wall of the building;b) applying sheathing to an outer surface of the studs;c) applying an elongate spacer device to an inner surface of the sheathing in a space defined by adjacent studs, the spacer device having a body that permits moisture to pass therethrough; andb) disposing insulation material proximate the spacer device, wherein the spacer device defines a vertically-oriented ventilation channel between the building sheathing and the insulation material, wherein the spacer body permits moisture to be passed from the insulation material through the body of the spacer device into the ventilation channel.

10. The method of claim 9, wherein the spacer device is defined by an openwork of polymeric fibers.

11. The method of claim 9, wherein the spacer device further includes a plurality of struts oriented obliquely with respect to the body, wherein the struts help the vertically-oriented ventilation channel between the building sheathing and the insulation material.

12. A method of constructing a building structure comprising: a) forming a portion of a building structure from a plurality of studs or rafters;b) applying sheathing to an outer surface of the studs or rafters;c) applying a spacer layer to an inner surface of at least one of the sheathing, the studs, and the rafters on the inner surface of a framing cavity defined by the sheathing and adjacent studs or rafters, the spacer layer having a body that permits moisture to pass therethrough; andd) spraying foam insulation over the spacer device, sheathing and the studs or rafters, wherein the spacer layer defines at least one ventilation channel between the spray foam insulation material and the sheathing, studs or rafters to permit moisture to be passed from the sheathing, studs or rafters into the at least one ventilation channel to permit the moisture to be evacuated from the building structure.

13. The method of claim 12, wherein the spacer device is defined by an openwork of polymeric fibers.

14. The method of claim 12, wherein the spacer device further includes a plurality of struts oriented obliquely with respect to the body, wherein the struts help define the ventilation channel.