This disclosure relates to a system for mounting panels (e.g. for mounting panels/fabrics which can provide an acoustic solution such as acoustic panels, baffles, fins, blades and fabrics). Hereafter, such acoustic panels, baffles, fins blades and fabrics will collectively be referred to as “panels”. The panels may be mounted as a ceiling fixture, suspension or infill and/or may optionally be mounted to provide for different lighting effects. The panels may additionally or alternatively be mounted to form walls, partitions, borders, dividers, etc.
Acoustic insulation panels (e.g. panels, baffles, fins, blades, fabrics) are employed for various acoustic applications ranging from sound absorption, sound attenuation and reduction of acoustic reverberation. Such panels can be employed as cavity and ceiling infill products to reduce sound transmission through walls and ceilings and within rooms and large spaces. Such panels can also form walls, partitions, borders, dividers, etc. within rooms and large spaces. Acoustic panels can be used in various building types and applications including in offices, meeting rooms, educational facilities including lecture theatres and classrooms, theatres and entertainment venues, restaurants, libraries, live venues, sports venues and halls, residential apartments, health (e.g. hospital) and aged-care facilities, as well as in various commercial applications.
At present, there is no universal mounting system for acoustic insulation panels. In addition, existing mounting systems tend to be of metal (e.g. aluminium and steel) and are thus relatively heavy and/or labour intensive to install. Further, acoustic panel installation tends to be bespoke, with there being very few modular installation systems available.
It is to be understood that, if any prior art is referred to herein, such reference does not constitute an admission that the prior art forms a part of the common general knowledge in the art, in Australia or any other country.
Disclosed herein, in a first aspect, is a system for mounting a panel with respect to a structure (e.g. a ceiling, ceiling space, false ceiling, wall, frame, divider, partition, border, fixture, furniture, etc.). The panel can take the form of an acoustic panel, baffle, fin, blade or fabric but is not so limited.
The system of the first aspect comprises an elongate member. A base of the member is configured to enable it to be mounted with respect to the structure. Opposing sidewalls of the member extend from the base such that, when the member is viewed in profile (i.e. from the member end), the sidewalls are configured to define a neck portion that extends to an enlarged head portion of the member.
The elongate member typically takes the form of a channel (e.g. so that it may be formed as an elongate extrusion, such as from a metal, composite or plastic). However, in a variation, the elongate member may have a solid form (e.g. to have a rod-like or bar-like form) or may be of closed hollow section, but in each case the member still has the neck portion and enlarged head portion. In these latter cases the sidewalls and base can define respective sides/surfaces of the solid form or hollow section.
The system of the first aspect also comprises a panel. As above, typically the panel takes the form of an acoustic panel, baffle or fin. The panel has at least one recess formed in an edge thereof (e.g. to be located in an in-use upper edge when the panel is to be suspended, or in an in-use side edge when the panel is to be used as a divider, barrier, etc.). The at least one recess is configured to generally correspond to an external profile of the member. Thus, the recess can be provided with an inner recess portion that is enlarged to receive (e.g. snugly or closely) the member head portion. The recess can also be provided with an outer recess portion that is configured to receive (e.g. snugly or closely) the member neck portion. The outer recess portion opens out of the panel edge (e.g. to enable the member to be mounted with respect to the structure). In use, when the member is located in the panel recess, it is able to retain the panel to the member.
For example, one or both of the member and panel may be configured whereby the member can be slid laterally through the recess to retain the panel to the member. Additionally or alternatively, one or both of the member and panel may be configured whereby the member can be push-fit into the recess, via the open outer recess portion, to retain the panel to the member.
The panel can be configured to be mounted to each member in a generally orthogonal arrangement (e.g. each panel extends at a right angle to the longitudinal axis of each member). Alternatively, the panel can be configured to mount at an angle to each member (e.g. each panel extends at an angle other than ˜90° to the longitudinal axis of each member). Further, each member need not be straight, and may e.g. be curved.
The system of the first aspect can provide for “universal” panel mounting. In this regard, the system can accommodate a range of panel widths (e.g. ranging from 4 mm to 150 mm panel thicknesses). The system can also accommodate a range of panel lengths (e.g. multiple spaced members can be mounted with respect to the structure to support long panels). The member may be direct-fixed to the structure or may be suspended or spaced from the structure. Thus, the system can allow for quick and easy installation. The system may be factory prefabricated and may be supplied as a kit e.g. along with installation instructions. A kit may be supplied without panels. For example, preformed panels may be supplied separately to other components of the mounting system.
The system of the first aspect can be modular in that members and panels can each easily be adapted on site to suit the particular application, including by using member end caps and connectors, as outlined below. In some forms, as outlined below, the system of the first aspect may integrate lighting. In some forms, as outlined below, the member may also directly support there-within a panel in the form of a fin.
When the elongate member takes the form of an elongate channel, a base of the channel may be configured to be mounted with respect to the structure (e.g. to be direct-mounted to, or suspended or spaced from, the structure). The opposing spaced sidewalls of the channel can extend from the base to define the channel.
Typically, the channel is configured such that the base extends between and joins the channel sidewalls. Each sidewall may then extend to a distal end edge such that the sidewalls are spaced apart to define an opening to the channel. However, in a variation of the channel, the base may instead be defined by elongate, spaced base walls, whereby an opening between the base walls can be defined along the length of the base. In this variation, the channel sidewalls may be connected (e.g. as a continuous wall) instead of being spaced apart at their distal end edges.
In an embodiment, when the elongate channel is viewed in profile (i.e. from an end thereof), each channel sidewall may be configured to define an outwardly projecting step-formation at the juncture of the neck portion with the head portion. For example, a neck portion of the sidewall may extend generally orthogonally from the base to the step-formation. The step-formation may then comprise a step that projects out (e.g. laterally) from a neck portion of the sidewall. Then, a head portion of each sidewall may extend from its respective step (e.g. it may extend so as to form an acute angle with its respective step). The head portion of each sidewall may extend to a distal end edge of the sidewall. Alternatively, the head portion of each sidewall may extend such that the sidewalls are connected (e.g. as a continuous wall) instead of being spaced at their distal end edges.
In an embodiment, sides of the panel recess may also be configured to define corresponding inwardly projecting step-formations. The corresponding step-formations may be defined at the juncture of the inner recess portion with the outer recess portion. Thus, when the channel is located in the panel recess, the corresponding channel and panel step-formations may face each other (e.g. they may abut) to thereby retain the panel to the channel.
In an embodiment, each sidewall distal end edge may comprise an inwardly projecting lip that runs for a length of the sidewall (e.g. for the entire length or along discrete length(s) of the sidewall). For example, the lips may project towards each other. The lips may be configured to retain an elongate (e.g. strip-like) cover at an opening to the channel, such as by a snap- or slide-fit.
When the elongate cover is in the form of an elongate strip, it may be provided with a pair of elongate, spaced parallel flanges that project from and extend along a face thereof. A distal end edge of each such flange may be configured to interact with (e.g. by a snap- or slide-fitting) a respective formation defined at a corresponding distal end edge of each sidewall. In this way, the elongate cover can be readily retained at and thereby cover the opening to the channel. The elongate cover may be formed of the same material as the channel (e.g. a metal such as aluminium), and thus may comprise be opaque. The elongate cover may instead be formed of a different material to the channel (e.g. a light-transmissive and/or polymeric material such as PVC, polycarbonate, etc). When formed of a light-transmissive material (e.g. a translucent or transparent material such as a polymer), this can allow the channel to hold a source of light (e.g. an LED strip) and thereby release light in use (e.g. the released light can pass through the cover and fall onto and/or reflect from panel(s) or fabric mounted to the channel).
In an embodiment, an external side of the base (i.e. the side that typically faces the structure) may comprise an inwardly formed elongate recess. This recess may open out from the base, which can allow for a suitable fastening mechanism to be connected to the base. The opening to the base recess may be further defined by opposing and inwardly projecting lips that extend for a length of the base recess (e.g. for the entire length or for discrete portion(s) of the base recess). These lips can be employed to secure the suitable fastening mechanism.
In this regard, in an embodiment, the system of the first aspect may further comprise a mounting fixture (i.e. the mounting fixture can provide one such suitable fastening mechanism). The mounting fixture may be configured for mounting to the structure (e.g. directly or to be suspended/spaced therefrom).
A portion of the mounting fixture may be configured to locate within the base recess and be retained therein by the lips. For example, the mounting fixture may be elongate, with one end of the elongate mounting fixture being configured for mounting with respect to the structure. This one end may be directly mounted to (e.g. by being affixed within) the structure. Alternatively, this one end may be configured to be suspended or spaced from the structure (e.g. via a wire, rod, etc.). Further, this one end of the mounting fixture may be located at that portion of the mounting fixture that is located (i.e. protrudes) outside of the base recess in use (i.e. the mounting fixture can project away from the base in use).
The other end of the mounting fixture may be provided with a groove therein (e.g. a peripherally extending groove formation). The groove enables the other end of the mounting fixture to locate within the base recess—e.g. to be retained therein by the lips locating in the groove.
In an embodiment, a wall of the base recess may be countersunk on an opposite side of the wall to the base recess. The countersunk side may extend for a length of the base recess wall (e.g. for the entire length or for discrete length(s) of the wall). An LED strip light may be located in the countersunk side. The countersunk side may also be configured to have one or more fasteners secured thereat (e.g. for direct mounting of the base to the structure). Each fastener may pass through a respective aperture formed in the base recess wall, which aperture may also be countersunk to flush-mount a head of the fastener therein. In this way, the LED strip light may still be located in the countersunk side (i.e. the LED strip may cover each fastener head).
In an embodiment, each sidewall may further comprise an elongate flange that projects inwardly from an intermediate location of a respective sidewall. Each such flange may extend for a length of a main channel recess (e.g. for the entire length or for discrete section(s) of the main channel recess). The flanges may generally project towards each other. In an embodiment, each flange may be formed as a continuation of the step of the step-formation.
In an embodiment, each flange may comprise a lip that extends at an acute angle from a distal end edge of the flange and away from the base. In use, the spacing of the distal end edges of the flanges may be such that an elongate edge of panel, such as an acoustic fin, can be positioned between and be retained by the flanges. The acutely extending lips can help to guide the panel (e.g. fin) elongate edge between the flange distal end edges during its insertion into the channel.
In an embodiment, the panel may be formed of a deformable material such that the member (e.g. channel) may be push-fit into the recess at the panel edge. For example, the panel may be formed of a thermally bonded polymeric (e.g. polyester) fibre material or natural (e.g. wool) fibre material.
In an embodiment, the panel may comprise a number of discrete recesses spaced out along the edge thereof. Each recess can locate a respective member (e.g. channel) therein.
In an embodiment, each panel recess may comprise opposing inwardly-facing faces. The inward faces of the panel outer recess portion may taper outwardly at the panel edge such that these inward faces are able to engage with (and e.g. guide) corresponding external faces of the member (e.g. channel) sidewalls to thereby guide the member when it is push-fit into a respective panel recess via the open outer recess portion.
In an embodiment, the system of the first aspect may further comprise at least one end cap (i.e. typically two end caps per member). Each end cap may be configured for secure location at a respective end of the member. The end caps can e.g. aesthetically finish off an installation and can cover any sharp edges of the member ends. The end caps may be moulded from a plastic material, which may also be light-transmissive or opaque.
In one form, when the member is hollow, each end cap may comprise a boss that protrudes from a plate. The boss can be formed to have an external profile that generally corresponds to (e.g. closely matches) an internal profile of the hollow member. This can enable the end cap to be push-fit into the respective end of the member.
In another form, when the member is hollow, each end cap may take the form of a connector. The connector can have bosses that protrude from respective, opposite sides of a plate. Again, each boss can be formed to have an external profile that generally corresponds to (e.g. closely matches) an internal profile of the hollow member. Thus, each boss may be push-fit into an end of a respective hollow member such that the connector can extend between and connect hollow members end-to-end.
In an embodiment, each boss may comprise a number of elongate panel-retaining inserts that project from a surface of the plate. A first pair of inserts can be arranged to locate between each flange and the base. A second pair of inserts can be arranged to locate between each flange and a respective sidewall distal end edge. In use, the first and second inserts can cooperate with the flanges, base and sidewalls to retain the end cap to the member end.
Also disclosed herein is an elongate member for use with the system of the first aspect as set forth above. The member may be configured as set forth above.
Also disclosed herein is a panel for use with the system of the first aspect as set forth above. The panel may be configured as set forth above (e.g. to comprise at least one corresponding recess therein).
Also disclosed herein is an elongate cover for use with the system of the first aspect as set forth above. The cover may be configured as set forth above.
Also disclosed herein is an end cap for use with the system of the first aspect as set forth above. The end cap may be configured as set forth above.
Also disclosed herein is a mounting fixture when that mounting fixture is used with the system of the first aspect as set forth above. The mounting fixture may be configured as set forth above.
Also disclosed herein is a kit for use with the system of the first aspect as set forth above. The kit can comprise one or more of the channel, panel, elongate cover, or end cap or as set forth above. The kit can optionally comprise one or more mounting fixtures as set forth above. The kit may alternatively be supplied without panel(s), which may be supplied separately to other components of the mounting system.
Also disclosed herein is a method for mounting a panel as set forth above with respect to a structure. For example, the method can be employed to install one or more such panels using one or more elongate members as set forth above. The method can be used to install such panel(s) at or in relation to a ceiling, ceiling space, false ceiling, wall, frame, divider, partition, border, fixture, furniture, etc. The panel to be installed can take the form of an acoustic panel, baffle or fin, but again is not so limited.
The method comprises mounting a base of the elongate member with respect to the structure. The method also comprises mounting to the member a panel by way of locating the member in the panel recess. Typically, each member is pre-installed with respect to the structure, and the panel then mounted thereto, although each panel may first be secured to the (or each) member, and then each member may be installed at or with respect to the structure.
In one form of the method, the panel may be mounted to the member by a relative sliding of the member laterally through the recess (e.g. one or both or the panel and member may be slid). In another form of the method, the panel may be mounted to the member by push-fitting the member into the recess via the open outer recess portion (e.g. one or both or the panel and member may be push-fit to the other). The panel may be configured (e.g. it may be deformable) such that it can be both slide or push-fit to the member.
In one embodiment of the method, the panel may comprise a number of discrete recesses spaced out along the edge thereof. A number of members that correspond to the number of discrete panel recesses may be mounted in a spaced manner with respect to the structure. The panel may be pre- or post-installed to the corresponding number of members.
In one embodiment of the method, a number of panels may be mounted to the member(s), e.g. in a spaced manner. Thus, a given installation may comprise a number of spaced members and a number of spaced panels.
In one form of the method, each member may be mounted directly to the structure (e.g. via one or more fasteners). The fasteners may be installed directly though each member, or the fasteners may comprise one or more mounting fixtures (such as set forth above) that may be pre-installed at the structure and then the member may be mounted thereto.
In another form of the method, each member may be mounted indirectly to the structure (e.g. via one or more mounting fixtures, such as set forth above). For example, each member may be suspended or spaced with respect to the structure.
In one embodiment, the method may further comprise retaining an elongate cover to the or each member. For example, when multiple panels are mounted to the member(s), a discrete elongate cover may be retained at the member to locate between adjacent panels. A discrete elongate cover may also be retained at the member to locate between an end-most panel and a respective adjacent member end. Each discrete elongate cover may be configured as set forth above.
In one embodiment, the method may further comprise securing at least one end cap (typically two end caps) to a respective end of each member. Again, the end cap may be configured as set forth above.
In one embodiment of the method, the end cap may be a connector as set forth above (i.e. the connector may be located between so as to connect adjacent members end-to-end).
Also disclosed herein, in a further aspect, is a system for mounting a panel such as an acoustic panel, baffle or fin. The system of the further aspect can, for example, be configured to support a so-called “cloud” panel, baffle or fin. The system can e.g. allow the panel to be suspended from a structure. The system can e.g. allow a number of panels to be suspended from a structure.
The system of the further aspect comprises a first elongate member. A base of the first member is configured to enable it to be mounted with respect to a structure (e.g. at or suspended from a ceiling, ceiling space, false ceiling, roof, etc.). Opposing sidewalls of the first elongate member can extend from the base such that, in profile (i.e. when viewed from the member end), the sidewalls can define a neck portion that extends to an enlarged head portion of the first elongate member. Thus, in the system of the further aspect, the first (or each) elongate member can be as defined above for the first aspect.
The system of the further aspect also comprises a first panel. Typically, the first panel takes the form of an acoustic panel, baffle or fin. The first panel can be arranged to be located adjacent to the first elongate member. In this regard, an edge of the first panel can locate adjacent to the neck portion of the first elongate member, and a face of the first panel can locate adjacent to the head portion of the first elongate member. Thus, when the first member is mounted with respect to a structure (e.g. a ceiling, ceiling space, false ceiling, roof, etc.), the first member can support thereat a respective edge of the first panel (i.e. the first panel can likewise be mounted with respect to the structure).
For example, where the system of the further aspect only makes use of one elongate member, an opposite edge of the first panel may be supported by an opposing structure (e.g. a wall, post, etc.). Thus, one edge of the first panel can be supported by the first elongate member, and e.g. the opposing edge of the first panel may be supported at the wall, post, etc.
In an embodiment, the system of the further aspect may further comprise a second panel. Typically, the second panel also takes the form of an acoustic panel, baffle or fin. The second panel may be arranged to be located adjacent to an opposite side of the first elongate member to where the first panel is to be located. In this regard, an edge of the second panel can locate adjacent to the neck portion of the member, and a face of the second panel can locate adjacent to the head portion of the member. Thus, the one elongate member can support respective edges of first and second panels at either side thereof.
In an embodiment, the system of the further aspect may further comprise a second elongate member. The second elongate member may be located adjacent to the first elongate member, although typically it is spaced or extends therefrom in use. For example, in one variation, the second elongate member may be spaced parallel to the first elongate member, whereby a first panel can extend between and be supported at its opposing edges by the first and second elongate members. In another variation, the second elongate member may extend at an angle to the first elongate member, whereby a first panel can extend between and be supported at adjacent edges thereof by the first and second elongate members.
In an embodiment, the second elongate member may be arranged so as to support another (e.g. opposite or adjacent) edge of the first panel at the neck portion of the second elongate member, with the face of the first panel locating adjacent to the head portion of the second elongate member. Thus, the first panel can span between and be supported by the first and second elongate members in use.
For example, when the first panel is rectangular or square in shape, and where the first and second elongate members are spaced and parallel, the first panel can be supported at opposing edges, respectively, by the first and second elongate members. In another example, when the first panel is rectangular or square in shape, and where the second elongate member extends orthogonally from the first elongate member, the first panel can be supported at adjacent (i.e. corner) edges by the first and second elongate members.
In a further variation, the second elongate member can also be arranged to extend at a “non-orthogonal” angle to the first elongate member. This arrangement can define an “acute corner” and an “obtuse corner” between the first and second elongate members. A first (e.g. triangular-corner-type) panel may be configured to locate and be supported in the acute corner, and a second (e.g. a trapezoidal-corner-type) panel may be configured to locate and be supported in the obtuse corner.
In an embodiment, the second elongate member may be arranged to extend from an end of the first elongate member. Further, the second elongate member may extend from the first elongate member end at an orthogonal or non-orthogonal angle. Additionally, the second elongate member may extend from the first elongate member end from either an end of the second elongate member, or from an intermediate location of the second elongate member. In each such case, the first panel may span between the first and second elongate members whereby respective edges of the first panel are supported at the first and second elongate members. Further, a second panel may be arranged at an opposite side to the first panel.
In an embodiment, the system of the further aspect may further comprise third and, optionally, fourth elongate members. For example, the second elongate member may be arranged to oppose and be spaced apart from the first elongate member, and the fourth elongate member may be arranged to oppose and be spaced apart from the third elongate member. When the system comprises first to fourth elongate members, these may be arranged and employed to support a first panel having four sides (e.g. square, rectangle, rhombus, trapezium, etc.). In this regard, the first panel may be configured to locate between and be supported at respective edges thereof by the first, second, third and fourth elongate members.
For example, the third and fourth elongate members may extend between and join the first and second elongate members (e.g. form a closed body of elongate members). In this arrangement, the respective ends of the third elongate member may be located at respective ends of the first and second elongate members, and the respective ends of the fourth elongate member may be located at respective opposite ends of the first and second elongate members.
In an embodiment, the system of the further aspect may comprise more than four elongate members, which can be assembled and arranged in the various configurations as outlined above. For example, the resulting configuration may comprise a five or more-sided regular polygon (e.g. a closed body with equal length sides). Alternatively, the system may be configured in the form of an irregular polygon, i.e. sides of unequal length. The first and further panels to be supported thereat can be configured accordingly.
In an embodiment, the second panel may be configured to surround and be supported at respective inner edge(s) thereof by the first, second, third and, when present, fourth or more elongate members. For example, an inner aperture of the second panel may be configured with the same external shape as the configuration of the first, second, third, or more elongate members.
In an embodiment, the system of the further aspect may further comprise one or more clamping elements. Each clamping element can be arranged to clamp at least one panel to a respective elongate member. For example, each clamping element can be arranged to be connected to an elongate member at the base of the elongate member.
Each clamping element may be adjustable and can be arranged to apply a clamping force to a respective panel located at the elongate member. In this regard, each clamping element may be connected to a respective elongate member via a rod. Each clamping element may be rotated around the rod between a non-clamping and clamping position.
In a variation, the rod may be threaded, whereby the rod can be screw-adjusted to increase or to release the clamping force.
When in the clamping position, the force that is applied by each clamping element may act at a face of the panel that is opposite to the panel face that is located at the head portion of the elongate member. In an embodiment, each clamping element may be arranged at an elongate member to apply a clamping force to respective panels located at either side of the elongate member.
Embodiments will now be described, by way of example only, with reference to the accompanying drawings in which:
In the following detailed description, reference is made to accompanying drawings which form a part of the detailed description. The illustrative embodiments described in the detailed description, depicted in the drawings and defined in the claims, are not intended to be limiting. Other embodiments may be utilised and other changes may be made without departing from the spirit or scope of the subject matter presented. It will be readily understood that the aspects of the present disclosure, as generally described herein and illustrated in the drawings can be arranged, substituted, combined, separated and designed in a wide variety of different configurations, all of which are contemplated in this disclosure.
The particular form of the system 10 as illustrated comprises a number of components, including an elongate member in the form of a channel 12. Other channel profiles are illustrated in
Other components of the system, as illustrated in
The channel 12 will initially be described. The channel 12 has a particular type of profile (see especially
Channel 12 is typically in the form of an extrusion, such that it may be extruded from metal, composite or plastic. However, in a variation to a channel, the elongate member can have a solid form (e.g. to have a rod-like or bar-like form) but can still be formed to have a neck portion and an enlarged head portion. In this case, the elongate member is not able to support therewithin a light source (such as described below). Further, to enable it to be secured with respect to a structure, the solid rod- or bar-like form may have pilot holes or other formations for fasteners (including for adhesives, or a mounting fixture, etc.).
The channel may have other forms (see e.g.
Each of the opposing channel sidewalls 13 is configured to define an outwardly projecting step-formation in the form of step 15 (i.e. at the juncture of the neck N with the head H). In the channel 12, walls 17 of neck N extend generally orthogonally from the base 14 to the step 15. The step 15 then projects laterally out from each wall 17. The head H comprises walls 19 that each extend from a respective step 15 at an acute angle to a distal end edge 21 of the wall 19. The distal end edges 21 are spaced to define an open end 25 of the channel 12. Alternatively, the walls of the head H can extend such that they are connected (e.g. as a continuous wall), instead of being spaced at their distal end edges (see e.g. the channel embodiments of
The base 14 of the channel 12 is configured to enable it to be mounted with respect to the structure. For example, in the embodiment shown in
Drill holes or pilot holes can optionally be spaced out along the planar wall of base 14, 14′, 14″ to allow for e.g. structure-securing screws, bolts, etc. to be driven up through the base wall 14, 14′, 14″ so as to mount the channel 12 with respect to (e.g. directly to) the structure.
Referring particularly to
In the system embodiment of
As shown in
Typically, the groove 57 extends peripherally around the body 55. The groove 57 also defines a head 59 at the in-use lower end of the body 55.
The groove 57 enables the lower end of the body 55 to be slid into the recess 16 from one end of the channel 12. In this regard, and as best shown in
Referring again to
The distal end edge 21 of each head wall 19 comprises an inwardly projecting lip 30 that runs for a length of the wall 19 (e.g. for the entire length or for discrete length(s) of the wall 19). The lips 30 are arranged to oppose and project towards each other. As best shown in
As best shown in
Where multiple panels 40 are to be secured to the channel(s) 12, a number of discrete length covers 70, 70′, 70″, etc. can be employed to between e.g. respective panels 40, 40′, 40″ (see e.g.
For example, as best shown in
Each cover 70 can be formed of the same material as the channel (e.g. a metal such as aluminium, plastic, etc.). The cover 70 can be formed from an opaque material. Alternatively, the cover 70 can be formed of a different material to the channel (e.g. from a light-transmissive and/or polymeric material such as PVC, polycarbonate, etc). When formed of a light-transmissive material (e.g. a translucent or transparent material such as a polymer), the channel can hold a source of light (e.g. an LED strip light 78—
Referring again to
In this regard, two related fin-retaining assemblies 75 are respectively shown in
As shown in each of
The system also comprises a panel 40. As above, typically the panel takes the form of an acoustic panel, baffle or fin. Each panel 40 can be formed of a deformable material such that the channel 12 (e.g. channel) may be push/press-fit into a recess 42 located at a panel edge (e.g. long edge). For example, the panel can be formed of a thermally bonded polymeric (e.g. polyester) fibre material or natural (e.g. wool) fibre material.
As best shown in
As best shown in
In use, when the channel 12 has been located in the panel recess 42, the panel 40 effectively becomes retained to the channel 12. For example, the channel 12 can be slid laterally through the recess. Additionally or alternatively, the channel 12 can be push- or press-fit into the recess 42, via the open outer recess portion. In this latter case of push/press-fitting of the channel into the recess 42, usually the panel deforms, however, the channel 12 may also be formed of e.g. a deformable material (e.g. polymer) that, to at least some extent, also deforms.
In
The upper sides of the outer recess portion 45 are also configured at 47 to taper outwardly (i.e. to open up the entranceway to the outer recess portion 45). The angle of the taper 47 is selected to generally match the angling of the head walls 19. In this way, the passage (e.g. push- or press-fit) of the head H of channel 12 into the recess 42 is facilitated, with the tapered sides 47 guiding the head H into the recess 42.
As set forth above, the system 10 further comprises at least one end cap to close off a respective end of a hollow channel 12. The end cap can take two forms. As shown in
However, as shown in
Usually the terminating end cap 60 and connector end cap 80, 80′ are each formed (e.g. moulded from plastic) as a unitary item. The end caps 60 and 80, 80′ can optionally be formed of a light-transmissive or opaque material. The end caps 60 and 80 can e.g. aesthetically finish off a system installation 10 and can cover any sharp edges of a respective channel end.
As best shown in
The boss formation 62 could comprise a single projection, however for ease of use (e.g. to account for manufacturing tolerances) it typically comprises a series of boss inserts in the form of a first pair of opposing neck bosses 65 and a second pair of opposing head bosses 67. Each boss pair projects from the same side of plate 64.
As best shown in
Again, each boss formation 82, 83 could comprise a single projection, however, again for ease of use (e.g. to account for manufacturing tolerances) each boss formation 82, 83 typically comprises a series of boss inserts. Thus, each boss formation 82, 83 comprises a first pair of opposing neck bosses 85 and a second pair of opposing head bosses 87. However, it will be seen in the connector end cap 80′ variation of
Each boss pair 85, 87, 87′ of each boss formation projects from the same respective side of plate 84. Again, the neck bosses 85 are sized and spaced so as to respectively and closely interface with inside faces of the base 14 and walls 17 of the channel neck portion N, and the head bosses 87, 87′ are sized and spaced so as to respectively and closely interface with inside faces of the step 15 and walls 19 of the channel head portion H.
It will also be seen that the plate 84 of the connector end cap 80, 80′ has an aperture 88 formed therethrough. This can allow e.g. the LED strip light 78 to be fed therethrough, form one channel to the next, as well as other services (e.g. cables, conduits, etc.).
In
Referring now to
Referring now to
Referring now to
The enlarged head portion H(bulb) of the bulbous profile 110 comprises a rebate 114 (i.e. at a location that opposes the opening 112). The rebate 114 comprises a wall 116 that runs for a length of the profile 110 (e.g. for the entire length or for discrete length(s) thereof). An LED strip light 78 can be secured to wall 116 to locate within the rebate 114.
Further, to enable the profile 110 to be secured with respect to a structure, the base wall strip portions 14″ can have apertures, pilot holes or other formations for respective fasteners (including for adhesives, or a mounting fixture, etc.).
The system 10 as described herein can provide for “universal” panel mounting. In this regard, the system 10 can accommodate a range of panel widths (e.g. ranging from 4 mm to 150 mm panel thicknesses). The system 10 can also accommodate a range of panel lengths (e.g. more than two spaced channels 12 can be mounted with respect to a given structure to support very long panels).
Because each channel 12 can be suspended (e.g. spaced) or direct-fixed to a structure, the system can allow for quick and easy installation. The system 10 can be factory prefabricated in a factory (e.g. according to the specifications of a given site). The system 10 can be supplied as a kit (e.g. along with installation instructions). The kit can comprise one or more (typically two) channels, one or more panels, a set of covers, end caps and connectors, two mounting fixtures per channel (i.e. four/kit), each being as set forth above. The channels, covers, end caps, connectors and mounting fixtures of the kit may be supplied separately and without the panels. For example, panels may be pre-formed and supplied separately to other components of the kit.
The system 10 is modular, in that channels 12 and panels 40 can each easily be adapted (e.g. joined and/or resized) on site to suit the particular application, including by making use of the kit including the covers 70, terminating end caps 60 and connector end caps 80, as outlined above.
Referring now to
As illustrated by
As illustrated by
As illustrated by
As illustrated by
As illustrated by
As indicated above, it will be understood that steps of the method as described herein can be varied to accommodate differing numbers of channels, channel lengths, channel spacings, panels, panel lengths, panel widths and panel thicknesses. Also, a number of panels may be mounted to the channel(s) in a variable (rather than evenly) spaced manner, and a multi-channel spacing may be uneven. Thus, a given installation may comprise any number of variably spaced channels and any number of variably spaced and varying panels. Different combinations of channel and member types can also be employed.
It should also be understood that, whilst each panel 40 has been shown (and has been configured) to be mounted to each channel 12 in a generally orthogonal arrangement (i.e. each panel 40 is shown extending at a right angle to the longitudinal axis of each channel 12), the panel 40 can be reconfigured to mount at an angle other than ˜90° to the longitudinal axis of each channel 12. Further, whilst each channel 12 has been depicted as being straight, one or more of the channels 12 may be curved, angled or generally non-linear, with the panel(s) and recesses 42 being reconfigured accordingly.
Each of the opposing channel sidewalls 13 is configured to define an outwardly projecting step-formation in the form of step 15 (i.e. at the juncture of the neck N with the head H). In the channel 12, walls 17 of neck N extend generally orthogonally from the base 14 to the step 15. The step 15 then projects laterally out from each wall 17. The head H comprises walls 19 that each extend from a respective step 15 at an acute angle to a distal end edge 21 of the wall 19. The distal end edges 21 are spaced to define an open end 25 of the channel 12. Alternatively, the walls of the head H can extend such that they are connected (e.g. as a continuous wall), instead of being spaced at their distal end edges (see e.g. the channel embodiments of
Referring now to
When channel 12 is employed to provide a cloud panel mounting arrangement, and as best shown in
However,
Further,
In the basic form of system 100, just side edge 141 of panel 140 is supported at a single channel 12. An opposite side of panel 140 can be supported at some other structure, such as a post, panel, wall, etc. For example, the panel could span between a wall and the channel 12. However, typically the channel 12 and panel 140 form part of a suspended “cloud” system. These more complex forms of the system 100 will now be described.
In this regard, the system 100 can comprise a second panel 142. Panel 142 is similar to panel 140, although it is configured/shaped differently (i.e. in the embodiment of
As best shown in
Additionally, in a yet more complex form, the system 100 can comprise parallel and spaced-apart transverse channels 120 and 120′. The transverse channels are each arranged to extend between the channels 12, 12′ as shown in e.g.
In this regard, in the embodiment of
Further, in the embodiment of
Further, it will be seen that a respective leg 149 and 149′ of each clamp 144 is arranged to clamp and hold a respective side edge of the panels 140, 142 against the channels 12, 12′. In this regard, to hold the panels 140, 142 in place within the mounting frame, only the channels 12, 12′ need be provided with a respective pair of spaced clamps 144.
Additionally, to suspend the mounting frame from a structure (e.g. ceiling, roof, false-ceiling, etc.), only the channels 12, 12′ need be provided with a respective pair of spaced mounting fixtures 50.
Referring in particular to
In use, each clamp 144 can be rotated with respect to its rod 148 between a non-clamping orientation (i.e. legs 149, 149′ sitting above a respective channel 12, 12′) and a clamping orientation (i.e. legs 149, 149′ sitting above a respective side edge of panels 140, 142). When each clamp is in the non-clamping orientation, the panels 140, 142 can be dropped into place on the mounting frame. Thereafter, the clamps can be rotated into the clamping orientation to secure each panel 140, 142 to its respective channel 12, 12′, 120, 120′. As best shown in
In a variation of the clamp 144, the in-use lower end of the rod 148 can be mounted to the base 14 of channels 12, 12′ as per the mounting fixture 50 described above. However, an opposing in-use upper end of the rod 148 can be externally threaded to engage with a corresponding internally threaded hole defined in the center of clamp central part 151. Thus, once each clamp 144 has been rotated into the clamping orientation (legs 149, 149′ above panels 140, 142), the rod 148 can be rotated (e.g. screw-driven) relatively to the threaded hole of clamp central part 151, in a manner that drives the legs 149, 149′ down securely into the panels 140, 142.
In the system 100, one or more of the channels 12, 12′, 120, 120′ can hold a source of light (e.g. an LED strip) and thereby release light in use. In the embodiment shown in
Typically, in-use, the system 100 hangs freely from a structure (e.g. ceiling, roof, etc.) in a substantially horizontal orientation, to function as a so-called cloud panel. However, it should be understood that, whilst the embodiments of system 100 are illustrated as generally horizontal, system 100 may be inclined at angles other than horizontal (i.e. at angles greater to or less than horizontal). Further, rather than being suspended, the system may be affixed to the underside of a ceiling, roof, etc.
It should be understood that, whilst the embodiments illustrated are rectangular in shape, the channels 12, 12′, 120, 120′ can be reconfigured (e.g. in length, number and angle of extent to other than)—90° to form alternative, e.g. regular or irregular polygons (i.e. with irregular polygons having channels of unequal length). For example, embodiments of the mounting frame may comprise less or more than four channels 12, 12′, 120, 120′ (e.g. three, five, six, seven, etc. channels) arranged as closed polygonal shapes. Further, whilst each channel 12, 12′, 120, 120′ has been depicted as being straight, one or more of the channels may be curved or generally non-linear. The panels 140, 142 can be reconfigured according to the shape of the mounting frame.
In another embodiment, the mounting frame may be configured to form an open body shape (as opposed to the closed body shape of
In this regard, and as best shown in
In another open mounting frame embodiment, a first channel 12 can be arranged at an angle to a second channel 12′. As best shown in
In the claims which follow and in the preceding description, except where the context requires otherwise due to express language or necessary implication, the word “comprise” or variations such as “comprises” or “comprising” is used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the system and method as disclosed herein.
Number | Date | Country | Kind |
---|---|---|---|
2018904819 | Dec 2018 | AU | national |
2019901268 | Apr 2019 | AU | national |
This application is a continuation of U.S. application Ser. No. 17/416,010, filed Jun. 18, 2021, which is the U.S. national stage entry, under 35 U.S.C. § 371, of International Application No. PCT/AU2019/051350, filed Dec. 10, 2019, which claims the benefit of and priority to Australian Application No. 2019901268, filed Apr. 12, 2019, and which claims the benefit of and priority to Australian Application No. 2018904819, filed Dec. 18, 2018, all of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
Parent | 17416010 | Jun 2021 | US |
Child | 18391395 | US |