The application relates generally to whole house fan (WHF) assemblies, and more particularly to bottom mounted WHF assemblies.
Whole house fans (WHF) are used to draw hot air from a house into the attic by means of a fan, with the hot air being exhausted out of the attic grates. Cooler air from outside is drawn into the house through an open door or window to provide for natural ventilation without the expense of an air conditioning compressor.
WHFs have been provided that are suspended from roof rafters. As understood herein, this design, in attempt to dampen vibration from the fan for sound quieting, poses several technical problems and drawbacks.
Accordingly, in one aspect an assembly includes at least one fan housing, at least one fan mounted in the fan housing, and at least one intake plenum configured to be mounted on at least one structure of a ceiling in a building above an opening of the ceiling. At least one air duct is configured for connecting the fan housing to the intake plenum such that the fan when energized can draw air in through the opening of the ceiling, the intake plenum, and the duct and exhaust air into an attic of the building. The assembly also includes at least one strut configured for vertical mounting on structure of the ceiling at a lower end of the at least one strut and to the fan housing at an upper end of the at least one strut.
In some implementations, the air duct may be flexible. The air duct may also have a first end connectable to the intake plenum and a second end connectable to the fan housing so that the fan when connected to the air duct may draw air in the building through the intake plenum and duct and exhaust the air in the attic. Also, in some implementations, the assembly may include a sound dampener interposed between the at least one strut and the fan housing, and/or interposed between the at least one strut and structure of the ceiling to which the at least one strut is mounted.
Furthermore, in some examples the assembly may include at least one arcuate collar that may be configured to be engaged with a top portion of the at least one strut. In these examples, the arcuate collar may be spaced from the fan housing along at least a segment of the collar and may be coupled to the fan housing by respective first and second couplings at opposed ends of the collar.
Also, in some examples, the assembly may include at least first and second struts, where each of the first and second struts may be configured for vertical mounting to structure of the ceiling. In these examples, the assembly may also include a first non-rigid connector configured for attachment to the first strut and to the fan housing to suspend the fan housing from the first strut, as well as a second non-rigid connector configured for attachment to the second strut and to the fan housing to suspend the fan housing from the second strut. Thus, if desired in these examples the assembly may further include a first ear hook configured for attachment to the fan housing and configured for connection to the first strut via the first non-rigid connector, as well as a second ear hook configured for attachment to the fan housing and configured for connection to the second strut via the second non-rigid connector. The first non-rigid connector may include a first strap, cable, and/or wire that is configured for attachment to an upper surface of the first strut, while the second non-rigid connector may include a second strap, cable, and/or wire that is configured for attachment to an upper surface of the second strut. Still further, if desired the assembly may include at least one crossbar configured for horizontal mounting on structure of the ceiling and configured to vertically mount the first and second struts on structure of the ceiling.
In another aspect, an assembly includes an intake plenum mountable over an opening in a ceiling of a building to be supported on one or more ceiling beams in an attic of the building. The assembly also includes a flexible duct having a first end connectable to the intake plenum and a second end connectable to housing of a fan so that the fan when connected to the duct draws air in the building through the intake plenum and duct and exhausts the air into the attic. The assembly further includes at least one strut configured for vertical connection to a ceiling beam or support surface at a lower end of the strut and to the housing of the fan at an upper end of the strut. The assembly also includes a sound dampener interposed between the strut and the fan housing, and/or between the strut and the ceiling beam or support surface to which the strut is attached.
If desired, in some examples the sound dampener may include at least one collar engageable with the upper end of the strut, with the collar being engageable with the housing at opposing ends of the collar and being spaced from the housing while engaged with the housing. Also, in some examples, the collar may include an inner band and an outer band generally parallel to the inner band and spaced from the inner band along at least a segment of the collar.
In some implementations, the sound dampener may include at least one resilient grommet. Also, in some implementations, the strut may include a first segment and a second segment slidably engaged with the first segment in a first configuration and not slidably engaged with the second segment in a second configuration. The second segment may include a U-shaped channel configured for receiving the first segment and may include plural bendable tabs on a bottom end of the second segment for flush engagement with the structure of the ceiling.
In still another aspect, an assembly includes at least one fan housing, at least one fan mounted in the fan housing, at least one intake plenum configured to be mounted on at least one structure of a ceiling in a building above an opening of the ceiling, and at least one air duct configured for connecting the fan housing to the intake plenum such that the fan when energized can draw air in through the opening of the ceiling, the intake plenum, and the duct and exhaust air into an attic of the building. The assembly also includes at least a first strut configured for vertical mounting on structure of the ceiling, at least a first non-rigid connector configured for attachment to the first strut and to the fan housing to suspend the fan housing from the first strut, at least a second strut configured for vertical mounting on structure of the ceiling, and at least a second non-rigid connector configured for attachment to the second strut and to the fan housing to suspend the fan housing from the second strut.
In some examples, the first and second non-rigid connectors may respectively include one or more straps, cables, and/or wires that may be configured for respective attachment to the first and second struts. The first and second non-rigid connectors may even be configured for attachment to the fan housing via respective ear hooks coupled to the fan housing, and each of the first and second non-rigid connectors may be configured to establish a loop that engages a respective ear hook coupled to the fan housing.
Still further, in some implementations the assembly may include a crossbar. The crossbar may be configured for mounting on structure of the ceiling and configured to vertically mount the first and second struts on structure of the ceiling.
In still another aspect, a method includes vertically mounting at least one post on a ceiling structure in an attic, engaging the at least one post with a housing of a fan, and dampening at least some vibration from the fan from propagating to the post.
The details of the present application, both as to structure and operation, can best be understood in reference to the accompanying drawings, in which like reference numerals refer to like parts, and in which:
An air duct 24, which may be flexible, which may be thermally insulated, and which may be acoustically insulated, connects the fan housing 12 to the intake plenum 16 such that the fan 14 when energized draws air in through the opening 22 of the ceiling, the intake plenum 16, and the duct 24, exhausting the air into the attic 18 from whence the air may be vented through roof vents to atmosphere.
The assembly 10 also includes at least one start 26 configured for vertical mounting on structure of the ceiling/attic floor. Consistent with present principles, at least one arcuate collar 28 is configured to be engaged with a top portion 30 of the strut 26, with the arcuate collar 28 being spaced from the fan housing 12 as shown along at least a segment 32 of the collar and coupled to the fan housing 12 by respective dampening couplings 34 at opposed ends of the collar and by a third dampening coupling at the strut-housing interface, it being understood that the resilient members of the dampening couplings are substantially identical in configuration and operation.
Referring briefly to
Because the side couplings 34 are located slightly rearward (relative to the direction of fan exhaust) relative to the bottom coupling 34 on the fan housing 12, the front of the fan housing 12 tilts slightly downward relative to the horizontal axis “H” at an angle α of, e.g., one to fifteen degrees, meaning the rear of the fan housing tilts slightly up. An oblique angle β is established with respect to the horizontal by the top surface of the damper 16 and the damper 16 oriented with its top surface tilted slightly toward the fan as shown. With the slight upward tilt of the rear of the fan housing that connects to the duct 24 and the described tilt of the top surface of the damper 16 which also connects to the duct 24, bends of the duct 24 are lessened.
As shown in
The fan housing 12 may also include a grill 208 that covers the exhaust end defined by the cylindrical exhaust segment 202. As shown in
Each coupling 34 includes a resilient member made of one or more pieces of deformable, resilient rubber or plastic. In the example shown and now referring to
In addition to the grommet 216, inboard and outboard resilient, preferably rubber cushioning washers 218, 220 straddle the end disks of the grommet 216. One or both washers 218, 220 may have a respective metal support washer or clip 222 on the side of the washer that is opposed to the grommet 216, so that a fastener such as a screw can pass through the support clips 222, washers 218, 220, and grommet 216 and engage, e.g., a nut 226 (
Note that the outer clip 222 as best shown in
At least the outer band 38 may also include a front tab 232 parallel to the rear tab 230, and if desired the inner band 36 likewise may include a front tab parallel to its rear tab and flush against the front tab 232 of the outer band 38. As best shown in
The shroud 200, grill 208, strut 26, and collar 28 typically are made of metal, although other materials such as hard plastic or composite materials may be used.
Now referring to
In examples, plural bendable tabs 706 may be provided on a bottom end of the outer segment 700 for flush engagement with the structure of the ceiling/attic floor, in the example shown, with a ceiling joist 708. Each tab 706 may be formed with two screw holes 710, with the proximal screw hole being engaged with a screw to fasten the strut to the joist 708 in
In some examples and referring back to
Also,
Now in cross-reference to
In the example shown in
As may be appreciated from
Furthermore, if desired resilient members such as rubber washers 1308 may be disposed on each flat side of each tab 1304 to avoid direct contact between the tabs 1304 and the top surface 1300 (on inner sides of the tabs) and between the tabs 1304 and either of the bolt head or nut (on outer sides of the tabs). Additionally, or alternatively, rubber grommets may be used where the hole in each tab 1304 may wrap around the outside of the relatively smaller narrow middle portion of the grommet and the bolt may extend through the center of the grommet itself to engage the tab 1304 with the strut 1208. In either case, in embodiments where the tabs 1304 are composed of metal for example, direct metal-to-metal contact between the tabs 1304 and top surface 1300 may be avoided, as well as direct metal-to-metal contact between the tabs 1304 and either the bolt head or nut.
However, note that in other embodiments, only a single tab may be used rather than tabs extending distally in parallel. The single tab may attach to either of the top side or bottom side of the top surface 1300 or to another upper portion of the strut, with a resilient member 1308 such as a rubber washer or grommet interposed therebetween similar to as described above.
Still in reference to
Furthermore, in some examples a resilient member 1314 such as a rubber grommet may be used as a contact buffer between a respective S-clip 1310 and respective strap 1210. Thus, the resilient member 1314 may be incorporated into or positionable into the hole of the respective attachment member 1312 as a grommet or other vibration-dampening structure (e.g., rubber ring) so that the respective S-clip 1310 is fed through the grommet or other resilient structure 1314 to thus engage the S-clip 1310 with the strap 1210.
As indicated above, the other bend or hook of the S-clip 1310 may be positioned to engage the ear 1316 and, in so doing, an additional resilient member 1318 may be positioned between the contact point for the bend or hook of the respective S-clip and the reciprocal contact point for the respective ear 1316 itself. For example, a rubber grommet may be placed in the ear 1316 similar to the rubber grommet 216 being received within the respective ear 214 as described above, and/or the ear 1316 may be lined or coated with rubber to establish the resilient member 1318. Additionally, or alternatively, a rubber ring or liner to establish one of the resilient members 1318 may be positioned on the S-clip itself and circumscribe a segment of the S-clip 1310 establishing its contact point with the ear 1316.
Now specifically in reference to
In some examples, the crossbar 1320 may even include a centrally located joint 1322 at which opposing portions of the crossbar 1320 may be folded, e.g., for packaging and transportation. The joint 1322 may be a male/female mechanical hinge with reciprocal components on each side of the joint 1322. The joint also be established by a revolute or pin joint or another type of joint such as a living hinge. In any case, in extended form as shown when mounted to a ceiling or attic floor, the crossbar 1320 may span, e.g., sixteen or twenty-four inches on center beams of the ceiling/attic floor perpendicular to the beams, or at another angle to achieve desired fan direction.
If desired, the crossbar 1320 may even include one or more openings 1324 into which the struts 1208 may be folded from respective pivot points. As best shown in
Additionally, or alternatively, opposing spring-biased push buttons 1500 may be used instead of the screws 1328, as shown in the alternate example of
In any case, note in terms of the example shown in
However, also note that opposing spring-biased push buttons 1504 as shown in
In either case, once folded into the openings 1324 shown in both of
Now further describing
Also note that multiple sets of holes 1510 may be disposed on side walls of the crossbar 1320 at various transverse sections of the crossbar 1320. Each set of holes 1510 may be used to adjust where the struts 1208 engage the crossbar 1320 for mounting to the structure 1212. Thus, different sets of the holes 1510 that are located along same transverse segments of the crossbar 1320 at a same height but on opposing side walls may be used for mounting the struts 1208 via the buttons 1500 to the crossbar 1320, depending on the particular width or diameter of the fan housing 1202. This may facilitate use of a single crossbar 1320 for use with fans and housings of different sizes so that the struts 1208 may remain mounted vertical or at least substantially vertical when the housing is suspended, rather than at an oblique angle with respect to vertical.
Now in cross-reference to
As may be appreciated from
Each non-rigid connector 1600 may be established by one or more wires, cables, and/or straps made in whole or in part of metal (e.g., steel), plastic, composite, etc. Each connector 1600 may also have a powder coating and may be used to suspend the fan housing 1202 to a respective strut 1208. Moreover, as shown best in
As best shown in
Furthermore, as shown best in
For completeness, also note that a portion of a power cord 1618 that connects to an electrical outlet at one end to provide power the motor 1330 at its other end is shown in
Present principles discussed above allow for isolation or dampening of vibration while improving ease of installation, solving installation problems in high attics. Furthermore, present principles facilitate creating a pitch angle on the fan to improve air flow through the duct that cannot be created with a hanging fan, while achieving the same or lower quietness as a hanging fan.
While the particular device is herein shown and described in detail, it is to be understood that the subject matter which is encompassed by the present invention is limited only by the claims.
Components included in one embodiment can be used in other embodiments in any appropriate combination. For example, any of the various components described herein and/or depicted in the Figures may be combined, interchanged or excluded from other embodiments.
“A system having at least one of A, B, and C” (likewise “a system having at least one of A, B, or C” and “a system having at least one of A, B, C”) includes systems that have A alone, B alone, C alone, A and B together, A and C together, B and C together, and/or A, B, and C together, etc.
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Number | Date | Country | |
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Parent | 16145970 | Sep 2018 | US |
Child | 16515663 | US |