The present disclosure relates generally to air ducts and more specifically to inflatable air ducts.
Ductwork is often used to convey conditioned air (e.g., heated, cooled, filtered, humidified, dehumidified, etc.) discharged from a fan and to distribute the air to a room or other areas within a building. Ducts are typically formed of generally self-supporting sheet metal, such as steel, aluminum, or stainless steel. Some ducts, however, are made of pliable materials, such as fabric or flexible plastic sheeting.
Pliable ducts are often suspended from a horizontal cable or track by way of a series of connectors distributed along the length of the duct. The connectors may include snap-hooks, clips, rings, or other type of connector that can slide along the cable or track. The connectors preferably allow the fabric duct to be readily removed from its cable or track so that the fabric duct can be cleaned.
When a fan or blower forces air through a pliable duct to supply the room with air, the pressure of the forced air tends to inflate the duct. This can cause the duct to expand radially and longitudinally to a generally cylindrical shape. When the ventilating or other conditioning demand of the room is satisfied, the blower is usually turned off, which allows the duct to deflate and retract lengthwise.
Depending on the application and material of the duct, in some cases, a deflated pliable duct sags, which may create a poor appearance or interfere with whatever might be directly beneath the duct. If a blower rapidly inflates the duct, rapid expansion of the duct may create an objectionable snapping or popping sound as the duct suddenly becomes taut.
The term, “pliable” refers to a material that can be readily folded over onto itself and later unfolded and restored to its original shape without appreciable damage to the material. Fabric is one example of a pliable material, and sheet metal is an example of a material that is not pliable. The term, “inflated state” refers to an air duct that is pressurized, and the term, “deflated state” refers to an air duct that is depressurized. According to these definitions, the interior of the duct is at least slightly more expanded (longitudinally or radially) in the inflated state as compared to the deflated state.
In the example shown in
In the illustrated example, the duct's upstream end 20 is supported by a discharge flange and/or blower flange 32 of the blower 12, and the rest of the duct 16 is supported by various support structure. Examples of such support structure include, but are not limited to, a hoop 34 within the duct's interior 26, an overhead support member 36, and at least one hanger 38 coupling the overhead support member 36 to at least one of the following: the sidewall 18, the hoop 34 and/or a loop 40 that holds the hoop 34 to the sidewall 18. The term “loop” refers to any structure at least partially disposed within the interior of a pliable-wall air duct, wherein the structure captures and holds an internal hoop at a desired position within the duct.
The term, “overhead support member” refers to any structure for carrying at least some weight of the sidewall 18. In some examples, the overhead support member extends at least higher than a lowermost surface 42 of the sidewall 18. Examples of the overhead support member 36 include, but are not limited to a cable 36a, a wire, a strap, a chain, a bar, a rod, a track 36b (
The hoop 34 is any structure that helps hold the sidewall 18 expanded at least when the blower 12 is de-energized. In the examples illustrated in
In
Referring to the dual-cable example illustrated in
In addition or alternatively, the hangers 38 can suspend the duct 16 from a single overhead cable 36a (or other overhead support member), as shown in
In addition or alternatively, referring to an example air duct assembly 68 of
Although the hangers 38 and 70 of
To help maintain an internal hoop's perpendicularity relative to the longitudinal direction 24, an example air duct assembly 82 includes a dual-hoop structure 84 (e.g., dual-hoop structures 84a, 84b, 84c and 84d), as shown in
The dual-hoop structures 84 may be positioned within the duct 16, coupled to the duct, and/or coupled to any other structures in any suitable manner. For example, the dual-hoop structure 84 can be disposed within the duct 16 without being directly connected to any hanger, as shown in the center dual-hoop structure 84b of
To hold the duct 16 taut, in some examples, the bracket 78 urges the dual-hoop structure 84c away from the blower 12 to hold the sidewall 18 in tension between the blower flange 32 and the end cap 30. In some examples, the loops 40 (e.g.,
In some examples, a series of dual-hoop structures 84 are distributed in a spaced-apart arrangement along the length of the duct 16 and are attached to the overhead support 36 (e.g., cable, track, ceiling, etc.) such that the means for attachment (e.g., brackets 78, hanger 38, hanger 70, etc.) in combination with the series of the dual-hoop structures 84 subject the sidewall 18 to tension between the dual-hoop structures 84. This is similar to what is shown in
Referring to
In the illustrated example, the cable 36d is held taut between the brackets 90 and 92, wherein the bracket 90 extends through an opening 94 in the sidewall 18. In some examples, as shown in
Referring to
In the examples of
In the example shown in
In the illustrated example, the struts 114 are not helically coiled. In other examples, however, each strut 114 is partially “coiled” less than 360 degrees (e.g., 10 to 20 degrees) around the circumferential interior of the duct 16. Such partial “coiling” allows the full length of each strut 114 to lay against the sidewall 18 while still being sufficiently bowed for transmitting longitudinal tension to the duct 16. In some examples, an even number of partially “coiled” struts 114 (e.g., four, six, eight, ten struts, etc.) are slightly “coiled” in opposite clockwise/counterclockwise directions to negate duct-twisting forces of the struts 114 (e.g., see
An example air duct assembly 120, shown in
During installation of the air duct 16, the installer can manually pull the hanger 126 to the right (as viewed in
In the example of
When the cable clamp 56 has two opposing cam locks, as shown in
In some examples, the cam lock 162 is omitted to create a unidirectional cable clamp 168. The unidirectional cable clamp 168 can be used in place of the cable clamp 56 of
Unidirectional cable clamp 168 can be used in a wide variety of air duct assemblies including, but not limited to, the examples shown in
As mentioned earlier,
Referring to
In the example schematically illustrated in
In examples where the hangers 182 exert a pulling force along a tilted direction (neither parallel nor perpendicular to the longitudinal direction 24), such a pulling force may have a longitudinal component of force that transfers to the hoop 34 (transferred directly or via sidewall 18) to help hold the duct 16 taut and/or to help hold the hoop 34 substantially perpendicular to the longitudinal direction 24. In examples where the pulling force is purely in the longitudinal direction 24, the longitudinal component comprises the entire pulling force.
In the example illustrated in
In some examples, there is a difference in the magnitude and/or direction of the forces 184a-f to achieve the desired combination of duct tension and hoop substantial perpendicularity. Examples of such differences include, but are not limited to, the forces 184c-f having a greater magnitude than the forces 184a-b, the forces 184a-b having a greater magnitude than the forces 184c-f, the force 184a pointing in a downstream direction 190 while the forces 184c and 184e point in an upstream direction 192, and the force 184b pointing in upstream direction 192 while the forces 184d and 184f point in the downstream direction 190. The upstream direction 192 and the downstream direction 190 point in opposite directions but both lay parallel the longitudinal direction 24. The term, “upstream direction” and “downstream direction” are with reference to the primary flow direction of the air 10.
In some examples, the forces 184a, 184c and 184e all point in the same direction (for desired tension) but have a different magnitude (to hold the hoop 34c substantially perpendicular relative to the longitudinal direction 24). In some examples, the forces 184b, 184d and 184f all point in the same direction (for desired tension) but have a different magnitude (to hold the hoop 34d substantially perpendicular relative to the longitudinal direction 24). In some examples, each of the forces 184a-f point in the same direction. In some examples, the forces 184a, 184c and 184e each point in the upstream direction 192 while each of the forces 184b, 184d and 184f point in the downstream direction 190.
The example illustrated in
The hangers 182a and 182b provide longitudinal component of forces 185a and 185b, respectively. The forces 182a-b subject the duct 16 to longitudinal tension. A downward force 185g (via hoop weight and/or a hanger 182g) in combination with the force 185a subject the hoop 34a to a rotational moment 187 that helps maintain the hoop 34a substantially perpendicular relative to the longitudinal direction 24. Likewise, a downward force 185h (via hoop weight and/or a hanger 182h) in combination with the force 185b subject the hoop 34e to a rotational moment 189 that helps maintain the hoop 34e substantially perpendicular relative to the longitudinal direction 24.
In some examples, there is a difference in the magnitude and/or direction of the forces 185a, 185b, 185g and 185h to achieve the desired combination of duct tension and hoop perpendicularity. Examples of such differences include, but are not limited to, the forces 185g-h having a greater magnitude than the forces 185a-b, the forces 185a-b having a greater magnitude than the forces 185g-h, a force 185a′ pointing in the upstream direction 192 while the force 185g points vertically downward, and a force 185b′ pointing in the downstream direction 190 while the force 185h points vertically downward. The upstream direction 192 and the downstream direction 190 point in opposite directions but both lay parallel to the longitudinal direction 24. The terms, “upstream direction” and “downstream direction” are with reference to the primary flow direction of the air 10.
In the illustrated example, the struts 114 are not helically coiled. In other examples, however, each strut 114 is partially “coiled” less than 360 degrees (e.g., between about 10 and 20 degrees) around the circumferential interior of the duct 16 (e.g., see
In some examples, the air duct assembly 194 includes some means for assisting in holding the struts 114 in position. Examples of such means include, but are not limited to, a strut-engaging retaining ring at the hoop 34, a strut-engaging recesses in the hoop 34, straps, cables, chains, ropes, clips, hooks, and various combinations thereof.
It should be noted that any of the individual features (e.g., hangers, hoops, rims, spokes, loops, overhead support members, sidewalls, air ducts, brackets, cable clamps, frameworks, etc.) disclosed in one or more of
U.S. Pat. Nos. 6,280,320; 6,425,417; 8,434,526; US publication 2008/0113610 A2 and US publication 2012/0028562 A1 are incorporated herein by reference in their entireties.
As set forth herein, an example air duct assembly includes an air duct having an inflated state and a deflated state. The air duct includes a sidewall that is pliable. The sidewall defines an interior of the air duct and an external area outside the air duct. The air duct assembly also includes a first overhead support member in the external area outside the air duct and a second overhead support member in the external area outside the air duct. The first overhead support member and the second overhead support member defining a separation distance therebetween. The air duct assembly also includes a hoop disposed within the interior of the air duct. The hoop provides the sidewall with support in a radial direction that is substantially perpendicular to the longitudinal direction. The air duct assembly also includes a loop disposed within the interior of the air duct and fastening the hoop with respect to the sidewall and a first hanger coupling at least one of the sidewall, the loop, or the hoop to the first overhead support member. The first hanger transmits a first pulling force that subjects the sidewall to tension in the longitudinal direction when the air duct is in the deflated state. The air duct assembly also includes a second hanger coupling at least one of the sidewall, the loop, or the hoop to the second overhead support member. The second hanger transmits a second pulling force that subjects the sidewall to tension in the longitudinal direction when the air duct is in the deflated state. The first hanger and the second hanger are spaced apart from each other by virtue of the separation distance between the first overhead support member and the second overhead support member.
In some examples, at least one of the first hanger or the second hanger is elongate in a tilted direction that is angularly displaced out of collinear alignment with both the longitudinal direction and the radial direction, and at least one of the first pulling force or the second pulling force is along the tilted direction when the air duct is in the deflated state.
In some examples, the first pulling force and the second pulling force applied to the hoop create a rotational moment that maintains the hoop in a substantially perpendicular orientation relative to the longitudinal direction.
In some examples, the first hanger and the second hanger provide a first set of hangers and the air duct assembly also includes a second set of hangers where the second set of hangers being spaced apart from the first set of hangers with respect to the longitudinal direction, the first set of hangers and the second set of hangers pulling the sidewall in opposite directions parallel to the longitudinal direction. In some examples, the hanger includes the loop. In some examples, the hanger passes through an opening in the sidewall. In some examples, the first hanger includes a connector. The overhead support member is one of a cable and a track that is elongate in the longitudinal direction, and the connector is attached to one of the cable and the track so as to substantially prevent relative longitudinal movement between the connector and the overhead support member.
In some examples, the overhead support member includes a plurality of spaced apart cables that are elongate in the longitudinal direction. In some examples, the first hanger and the second hanger are spaced apart from each other by virtue of the separation distance between the cables. In some examples, the loop is one a plurality of loops circumferentially distributed around the hoop. In some examples, the air duct extends in the longitudinal direction from an upstream end to a downstream end of the air duct, and the hanger is at an intermediate position spaced apart from the upstream end and the downstream end.
An example air duct assembly for conveying air in a downstream direction, which is opposite an upstream direction, includes an air duct having an inflated state and a deflated state. The air duct is elongate in a longitudinal direction. The air duct includes a sidewall that is pliable. The sidewall to define an interior of the air duct and an external area outside the air duct. The air duct assembly includes first and second cables radially offset relative to the air duct. The air duct assembly includes a hoop providing the sidewall with support in a radial direction that is substantially perpendicular to the longitudinal direction. The air duct assembly includes a first hanger coupled to at least one of the hoop or the sidewall and the first cable where a first pulling force is transferred to the hoop or the sidewall from the first hanger. The air duct assembly includes a second hanger radially spaced apart from the first hanger and coupled to at least one of the hoop or the sidewall and the second cable where a second pulling force is transferred to the hoop or the side wall from the second hanger and where the first and second hangers is independently couplable and adjustable relative to the respective first and second cables or tracks.
In some examples, the first pulling force includes a first longitudinal component of force substantially parallel to the longitudinal direction and the second pulling force includes a second longitudinal component of force substantially parallel to the longitudinal direction where the first longitudinal component of force is distinguishable from the second longitudinal component of force by a characteristic that includes at least one of magnitude or direction. In some examples, the first longitudinal component of force is greater in magnitude than the second longitudinal component of force and a difference in magnitude between the first longitudinal component of force and the second longitudinal component of force subjects the hoop to a rotational moment that helps maintain a plane of the hoop substantially perpendicular to the longitudinal direction.
In some examples, the first longitudinal component of force points in the upstream direction and the second longitudinal component of force points in the downstream direction, and a difference in direction between the first longitudinal component of force and the second longitudinal component of force subjects the hoop to a rotational moment that helps maintain a plane of the hoop substantially perpendicular to the longitudinal direction.
An example air duct assembly includes an air duct having an inflated state and a deflated state. The air duct is elongate in a longitudinal direction and extending from an upstream end to a downstream end. The air duct includes a sidewall that is pliable. The sidewall being tubular to define an interior of the air duct and an external area outside the air duct. The air duct assembly includes a cable or track and first and second hangers suspending the air duct from the overhead support. The first and second hangers are spaced apart and distributed in the longitudinal direction between the upstream end and the downstream end.
The first and second hangers are non-perpendicular and non-parallel relative to the longitudinal axis to apply tension to the sidewall in the longitudinal direction.
In some examples, the first and second hangers are angularly displaced out of collinear alignment with both the longitudinal direction and a radial direction where the radial direction is perpendicular relative to the longitudinal direction. In some examples, the first and second hangers urge the sidewall in opposite longitudinal directions. In some examples, the first hanger or the second hanger is at an intermediate position between and spaced apart from the upstream end and the downstream end.
In some examples, air duct assembly includes a first dual-hoop structure proximate a third hanger where the first dual-hoop structure includes first and second hoops disposed within the interior of the air duct and a second dual-hoop structure proximate the fourth hanger where he second dual-hoop structure comprising third and fourth hoops disposed within the interior of the air duct.
In some examples, the air duct assembly also includes a fifth hanger proximate the first dual-hoop structure and being spaced apart from the third hanger where the third hanger is coupled to the first hoop and the fourth hanger is coupled to the second hoop to provide a first rotational moment that maintains the first and second hoops substantially perpendicular relative to the longitudinal direction.
In some examples, the air duct assembly also includes a sixth hanger proximate the second dual-hoop structure and spaced apart from the fourth hanger where the fourth hanger is coupled to the third hoop and the sixth hanger is coupled to the fourth hoop to provide a second rotational moment that maintains the third and fourth hoops substantially perpendicular relative to the longitudinal direction. In some examples, the fifth hanger exerts a downward force against the first dual-hoop structure.
An example air duct assembly includes an air duct elongate in a longitudinal direction. The air duct includes a sidewall that is pliable, the sidewall being tubular and defining an interior of the air duct and an external area outside the air duct. The air duct assembly includes an overhead support member in the external area outside the air duct and a hoop disposed within the interior of the air duct. The hoop provides the sidewall with support in a radial direction that is substantially perpendicular to the longitudinal direction and a bracket passing through an opening in the sidewall and extending from the hoop to the overhead support member. The bracket is more rigid than the sidewall and the bracket cooperating with the hoop to subject the air duct to tension in the longitudinal direction. The bracket and the hoop are non-adjustably coupled.
In some examples, the hoop includes an outer rim, and the bracket connects to the outer rim. In some examples, the hoop includes a central region, and the bracket connects to the central region. In some examples, the hoop includes an outer rim, a central region and a spoke extending between the central region and the outer rim, and the bracket connects to the spoke.
An example air duct assembly includes an air duct elongate in a longitudinal direction. The air duct includes a sidewall that is pliable. The sidewall defines an interior of the air duct and an external area outside the air duct. The air duct assembly includes a cable or track a first dual-hoop structure to provide the sidewall with support in a radial direction that is substantially perpendicular relative to the longitudinal direction. The air duct assembly includes a bracket connecting the first dual-hoop structure to the cable or track where the bracket being more rigid than the sidewall.
In some examples, the first dual-hoop structure includes a first hoop having an outer rim, and the bracket connects to the outer rim. In some examples, the first dual-hoop structure includes a first hoop having a spoke and a central region, and the bracket connects to at least one of the spoke or the central region. In some examples, the bracket connects to the framework of the first dual-hoop structure. In some examples, the air duct assembly includes a second bracket where the bracket connects to a first hoop of the first dual-hoop structure, and the second bracket connects to a second hoop of the first dual-hoop structure.
In some examples, the air duct assembly includes a second dual-hoop structure where the first dual-hoop structure and the second dual-hoop structure being spaced apart from each other, the first dual-hoop structure not being directly coupled to and independently movable relative to the second dual-hoop structure. In some examples, the air duct assembly is free of any appreciable airflow obstruction within the interior of the air duct between the first dual-hoop structure and the second dual-hoop structure. In some examples, the bracket and the first dual-hoop structure are to subject the air duct to tension in the longitudinal direction.
An example air duct assembly includes an air duct comprising a sidewall that is pliable where the sidewall defines an interior of the air duct. The air duct assembly includes a first hoop disposed within the interior of the air duct where the first hoop provides the sidewall with support in a radial direction that is substantially perpendicular to the longitudinal direction. The air duct assembly includes a cable disposed within the interior of the air duct. The cable is elongate in the longitudinal direction. The cable engages the first hoop to help support the weight of the first hoop and the sidewall.
In some examples, the first hoop includes an outer rim, a central region, and a spoke extending between the central region and the outer rim, and the cable connects to the central region. In some examples, the air duct assembly also includes a second hoop disposed within the interior of the air duct where the second hoop provides the sidewall with support in the radial direction and the cable engages the second hoop. The cable is in tension between the first hoop and the second hoop subjects the sidewall to tension in the longitudinal direction. In some examples, the air duct assembly also includes a dual-hoop structure that includes the first hoop and a second hoop similar to the first hoop, and a framework holding the first hoop spaced apart from the second hoop.
An example air duct assembly includes an air duct comprising a sidewall that is pliable, the sidewall defining an interior of the air duct and an external area outside the air duct and a strut being elongate in the longitudinal direction. The curved strut having opposite ends proximate the upstream end and the downstream end of the air duct, the strut being in compression between the upstream end and the downstream end subjects the sidewall to tension in the longitudinal direction.
An example air duct assembly includes an air duct having a sidewall that is pliable. The sidewall defines an interior of the air duct and an external area outside the air duct. The air duct assembly includes a curved strut elongate in the longitudinal direction. The curved strut has opposite ends proximate the upstream end and the downstream end of the air duct. The curved strut is in compression between the upstream end and the downstream end to subject the sidewall to tension in the longitudinal direction.
In some example examples, the air duct assembly includes an overhead support carrying weight of the air duct and the curved strut. In some example examples, the air duct assembly includes a hoop disposed within the interior of the air duct. The hoop provides the sidewall with support in a radial direction that is substantially perpendicular to the longitudinal direction. In some example examples, the air duct assembly includes a lug extending from the hoop to the external area outside the air duct, the curved strut engaging the lug. In some examples, the curved strut is in the external area outside the air duct. In some examples, the curved strut is within the interior of the air duct.
An example air duct assembly includes an air duct to have an inflated state and a deflated state. The air duct includes a sidewall that is pliable. The sidewall to define an interior of the air duct and an external area outside the air duct. The air duct assembly includes a first overhead support member to be in the external area outside the air duct and a second overhead support member to be in the external area outside the air duct. The first overhead support member and the second overhead support member to define a separation distance therebetween and a hoop to be disposed within the interior of the air duct, the hoop to provide the sidewall with support in a radial direction that is substantially perpendicular to the longitudinal direction. The air duct assembly includes a loop to be disposed within the interior of the air duct and to fastening the hoop with respect to the sidewall. The air ducat assembly includes a first hanger to couple at least one of the sidewall, the loop, or the hoop to the first overhead support member. The first hanger is to transmit a first pulling force that subjects the sidewall to tension in the longitudinal direction when the air duct is in the deflated state and a second hanger to couple at least one of the sidewall, the loop, or the hoop to the second overhead support member. The second hanger to transmit a second pulling force that subjects the sidewall to tension in the longitudinal direction when the air duct is in the deflated state. The first hanger and the second hanger are spaced apart from each other by virtue of the separation distance between the first overhead support member and the second overhead support member.
Although certain example methods, apparatus and articles of manufacture have been described herein, the scope of the coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
This patent arises from a continuation of U.S. application Ser. No. 17/339,517, which was filed on Jun. 4, 2021, and which claims priority to U.S. U.S. application Ser. No. 17/134,988 (now U.S. Pat. No. 11,543,149), which was filed on Dec. 28, 2020, and which claims priority to U.S. application Ser. No. 16/278,378 (now U.S. Pat. No. 10,876,758), which was filed on Feb. 18, 2019, which claims priority to U.S. application Ser. No. 15/474,751 (now U.S. Pat. No. 10,208,981), which was filed on Mar. 30, 2017, and which claims priority to U.S. application Ser. No. 14/290,543 (now U.S. Pat. No. 9,644,858), which was filed on May 29, 2014. U.S. application Ser. No. 17/339,517, U.S. application Ser. No. 17/134,988, U.S. application Ser. No. 16/278,378, U.S. application Ser. No. 15/474,751, and U.S. application Ser. No. 14/290,543 are hereby incorporated herein by reference in their entireties. Further, priority to U.S. application Ser. No. 17/339,517, U.S. application Ser. No. 17/134,988, U.S. application Ser. No. 16/278,378, U.S. application Ser. No. 15/474,751, and U.S. application Ser. No. 14/290,543 is hereby claimed
Number | Date | Country | |
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Parent | 15474751 | Mar 2017 | US |
Child | 16278378 | US | |
Parent | 14290543 | May 2014 | US |
Child | 15474751 | US |
Number | Date | Country | |
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Parent | 17339517 | Jun 2021 | US |
Child | 18458521 | US | |
Parent | 17134988 | Dec 2020 | US |
Child | 17339517 | US | |
Parent | 16278378 | Feb 2019 | US |
Child | 17134988 | US |