The described embodiments relate generally to plastic panels and barriers or other structures using such panels and methods of their formation. In particular, embodiments relate to plastic panels suitable for use in sound attenuation barriers or other wall structures. The plastic panels may be generally hollow.
Sound attenuation barriers are used internationally to attenuate the transmission of noise from a noisy area, such as a roadway, industrial site or other high noise area. Such barriers are generally required to provide a certain specified degree of attenuation of noise passing from one side of the barrier to the other.
Sound attenuation barriers commonly include support structure anchored to the ground and a series of panels spanning the support structure to provide a continuous barrier along a desired distance. In some instances, such sound attenuation barriers must extend for a number of kilometres. Commonly, the panels used in existing sound attenuation barriers are formed of wood, concrete and/or steel. These panels are formed at a remote site, transported to the place where the barrier is to be erected, then affixed relative to the support structure to form the sound attenuation barrier. Steel panels are heavy and expensive and subject to graffiti. Wood panels are subject to burning, are more prone to deterioration and need significant maintenance. Concrete panels are quite heavy and can be prone to cracking or chipping. As it is commonly preferred to have sound attenuation barriers provide an aesthetically appealing appearance, cracking or chipping of the panels is undesirable and the panel manufacturer may be required to replace any such damaged panel at its own cost. Further, concrete panel forming processes provide only limited flexibility to confer an appealing aesthetic appearance on an external face of the panel.
Another problem encountered in relation to sound attenuation barriers is the potential for vandalism, such as spray painted graffiti. Removal of graffiti from concrete panels can be problematic and expensive. Similarly, where a sound attenuation barrier is adjacent an area that throws up air-born particulate, such as a roadway, airborne pollutants commonly accrete onto the panels over time and need to be cleaned in order maintain an aesthetically pleasing appearance. For some panel materials, it can be hard to clean the pollutants from the panel surfaces.
It is desired to address or ameliorate one or more shortcomings or disadvantages associated with prior techniques for sound attenuation barriers and panels, or to at least provide a useful alternative thereto.
Throughout this specification the word “comprise”, or variations such as “comprises” or “comprising”, will be understood to imply the inclusion of a stated element, integer or step, or group of elements, integers or steps, but not the exclusion of any other element, integer or step, or group of elements, integers or steps.
Any discussion of documents, acts, materials, devices, articles or the like which has been included in the present specification is not to be taken as an admission that any or all of these matters form part of the prior art base or were common general knowledge in the field relevant to the present disclosure as it existed before the priority date of each claim of this application.
Some embodiments relate to a hollow plastic wall panel, the panel having a length greater than a width, a thickness less than the width, a front wall, an opposite back wall and opposed first and second long edge regions, wherein the panel comprises a first end and a longitudinally opposite second end, wherein the first long edge region defines at least one first recessed portion to longitudinally receive and mate with a first longitudinal support structure and wherein the second long edge region defines at least one second recessed portion to longitudinally receive and mate with a second longitudinal support structure.
The front wall may be formed to have a substantially continuous convex curvature across a front face of the front wall from adjacent the first long edge region to adjacent the second long edge region. A maximum distance of the front wall from the first and second long edge regions in the thickness direction due to the convex curvature may be between about 10 mm and about 30 mm.
The length of the panel may be between about 2 in and about 4 m. The thickness of the panel may be between about 15 cm and about 25 cm. The width of the panel may be between about 30 cm and about 100 cm. The panel may have a substantially hollow shell structure defined at least in part by the front and back walls. The shell structure may be substantially free of joining portions that extend between the front and back walls other than at the first and second ends and the long edge regions. The shell structure may be formed of at least one polyolefin material suitable for rotational moulding.
The panel may further comprise a plurality of spacer elements interposed between the front wall and the back wall. One or more of the spacer elements may be formed of moulded plastic. Each spacer element may have opposed outer edges to respectively brace against an inner surface of the front wall and an inner surface of the back wall. At least one of the spacer elements may have coupling structure to couple with cooperating coupling structure of another panel. Each of the spacer elements may be coupled to inwardly extending flanges of the front wall and the back wall.
Each of the spacer elements may have a first recessed portion at one end and a second recessed portion at an opposite end. The at least one first recessed portion of the panel may be defined at least in part by first recessed portions of the spacer elements, and the at least one second recessed portion of the panel may be defined at least in part by second recessed portions of the spacer elements. The at least one first recessed portion and the at least one second recessed portion may be defined in part by a gap that separates the front and back walls from each other.
The front wall may have a substantially consistent thickness. The first and second recessed portions may have substantially the same shape. The first and second recessed portions of the panel may be generally longitudinally extending and approximately u-shaped in cross-section. The first and second recessed portions may be defined by the panel to have a depth and a width, wherein the depth is about half of the width.
A first distance in the thickness direction of the first and second recessed portions from the front wall may not be equal to a second distance in the thickness direction of the first and second recessed portions from the back wall. The panel may be free of non-moulded longitudinal reinforcing structure.
The panel may define at least one locating recess to allow positioning of the panel in one or more specific positions in relation to cooperating structure on the first or second support structure. The panel may be configured to accommodate movement due to thermal expansion or contraction in the length direction or the width direction relative to the first and second support structure.
Attenuation of sound through the panel may be at least about 25 decibels at frequencies between 250 Hz and 5000 Hz. At least the front and back walls may be formed by rotational moulding. The panel may be for use in erecting a sound attenuation barrier near a roadway.
Some embodiments relate to a barrier comprising:
at least one panel as described above;
vertically extending support structure that is fixed relative to the ground; and
the first and second support structures coupled to the vertically extending support structure;
wherein the first and second support structures are respectively received in the at least one first recessed portion and the at least one second recessed portion so that the at least one panel is supported by the first and second support structure.
A first beam of the first and second support structures may be fixedly connected to the vertically extending support structure at a lowest beam position and at least a second beam of the first and second support structures may be clamped to the vertically extending support structure at a position vertically spaced above the lowest beam position to secure at least one panel between the first beam and the second beam. The panels may be positioned end-to end in a line between the first beam and the second beam:
Some embodiments relate to a method of erecting a barrier, comprising:
erecting vertically extending support structure that is fixed relative to the ground;
coupling at least two vertically spaced, horizontally extending support beams to the vertically extending support structure; and
positioning at least one panel described above to be supported in between two of the at least two horizontally extending support beams.
The coupling may comprise fixedly connecting a first one of the horizontally extending support beams to the vertically extending support structure at a lowest beam position and clamping at least a second one of the horizontally extending support beams at a position vertically spaced above the lowest beam position to secure at least one panel between the first one beam and the second one beam.
The coupling and positioning may be performed in sequence so that a lower support beam is coupled to the vertically extending support structure, then at least one panel is positioned to rest on the lower support beam, then an upper support beam is coupled to the vertically extending support structure to hold the at least one panel in between the lower support beam and the upper support beam. The positioning may comprise positioning two of the panels end-to-end in a line between two of the horizontally extending support beams.
Some embodiments relate to a method of manufacturing a plastic wall panel, the method comprising:
forming a plastic front wall and a plastic back wall, the front wall and the back wall having a generally same length, width and thickness;
positioning a plurality of spacers between the front wall and the back wall and coupling each of the spacers to the front wall and the back wall to substantially fixedly position the front wall in relation to the back wall in a generally aligned, longitudinally parallel, spaced, opposing arrangement.
wherein the front wall, the back wall and the spacers are configured to define a panel having a length greater than a width, a thickness less than the width, a first end and a longitudinally opposite second end, the panel having opposed first and second long edge regions, wherein the first long edge region defines at least one first recessed portion to longitudinally receive and mate with a first longitudinal support structure and wherein the second long edge region defines at least one second recessed portion to longitudinally receive and mate with a second longitudinal support structure.
The front wall and back wall may be formed by rotational moulding. The front wall and back wall may be formed separately.
Some embodiments relate to a method of manufacturing a plastic wall panel, the method comprising:
rotationally moulding a plastic wall panel shell, the shell having a length greater than a width, a thickness less than the width, a front wall, an opposite back wall and opposed first and second long edge regions, wherein the panel comprises a first end and a longitudinally opposite second end, wherein the first long edge region defines at least one first recessed portion to longitudinally receive and mate with a first longitudinal support structure and wherein the second long edge region defines at least one second recessed portion to longitudinally receive and mate with a second longitudinal support structure.
The front wall may be formed to have a substantially continuous convex curvature across a front face of the front wall from adjacent the first long edge region to adjacent the second long edge region. A maximum distance of the front wall from the first and second long edge regions in the thickness direction due to the convex curvature may be between about 10 mm and about 30 ram.
The shell may be moulded to have at least one bridging portion bridging between the front and back walls, the at least one bridging portion being positioned longitudinally inwardly of the first and second ends. The shell may be moulded to define at least one recess in the back wall at the first end. The shell may be moulded to define third and fourth recesses partly coinciding with the first and second recessed portions, respectively, at the first end.
The panel may be formed to have at least one bridging portion bridging between the front and back walls, the at least one bridging portion being positioned longitudinally inwardly of the first and second walls
The length of the panel may be between about 2 in and about 4 m. The thickness of the panel may be between about 15 cm and about 25 cm. The width of the panel may be between about 30 cm and about 100 cm. The panel may have a substantially hollow shell structure defined at least in part by the front and back walls.
Some embodiments relate to a cladding for a building, comprising support structure and a plurality of the wall panels described herein, wherein the wall panels are coupled to the support structure to form at least part of the cladding.
Some embodiments relate to a building exterior, comprising support structure and a plurality of the wall panels described herein, wherein the wall panels are coupled to the support structure to form at least part of the building exterior. Some embodiments relate to a building structure comprising a plurality of the panels described herein.
Embodiments are described in further detail below, by way of example, with reference to the accompanying drawings, in which:
Described panels may be formed by rotational moulding techniques using existing rotational moulding technology. Such techniques may involve formation of a mould, addition of plastic granules into the mould, closure of the mould and then simultaneous rotation and heating of the plastic inside the closed mould in order to melt the plastic evenly around the heated surfaces of the mould. Use of rotational moulding techniques in the context of forming embodiments of plastic panels is described herein in more detail in relation to
Described panels can be used to form walls or barriers or to form part of a building structure, for example. In some embodiments, described panels can be used together with support structures to form sound attenuation barriers that can extend for hundreds of metres and possibly kilometres. When used for such sound attenuation barriers, described panels provide for a lighter, less expensive and more easily transportable form of panel than the concrete panels of the prior art.
Referring now to
The front face of the front side wall 104 may be formed to have a textured external surface, as shown and described in relation to co-pending and co-owned International Patent Application No. PCT/AU2013/001177, the entire contents of which is hereby incorporated by reference. The textured external surface may have a stone (matte) appearance and may comprise a visually discernible pattern, such as geometric shapes or one or more symbols or parts of symbols. The one or more symbols may define one or more words or may convey a specific meaning, for example. Similarly, the back face of the back side wall 102 may be formed to have a textured external surface. The back surface may have a stone (matte) appearance and may comprise a visually discernible pattern, such as one or more symbols or parts of symbols. Such symbols or parts of symbols may define one or more words or convey specific meanings. Formation of panel 100 by rotational moulding allows the creation of varied visually aesthetically appealing or meaningful indicia or patterns to be provided on external exposed front and back faces of front and back walls 104, 102 of the panel 100, which may provide added appeal in some circumstances. Additionally, such surface variations can assist in strengthening the panel walls and/or hiding or at least visually obscuring some expansion or contraction in the plastic wall panels due to environmental temperature variation.
Each panel 100 has a length greater than its height and a height greater than its width when the panel 100 is oriented vertically in a normal vertical wall panel orientation as shown in
The example dimensions given here may be varied, depending upon requirements, and are intended to only be generally indicative of the dimensions of some embodiments. Other embodiments can have different dimensions. For example, the panel length may be shorter, in the order of 2, 2.5 or 2.75 metres or other lengths in between about 2 and 3 metres. The panel length may alternatively be longer than 3 metres, for example up to 3.5, 4, 4.5 or 5 metres or up to about 6 metres. Panels of such longer lengths will generally require suitable reinforcing structure, such as the support beams and/or other support framework described herein, in order to tolerate high wind loads.
In the context of this application, given that the plastic panels described herein are subject to thermal expansion and contraction and may also experience some degree of flexion, the term “about” applied to a dimension of a part or a structural component of a panel should be understood to include dimensions in a range, such as an absolute range or a percentage range like 1%, 2%, 3%, 4% or 5%, either side the specified dimension. For example, a length of “about three metres” may be understood to include lengths in the range of 50-100 mm more or less than three metres, which equates to a particular percentage range of variation.
In some embodiments, the panel 100 may be formed during the moulding process to define shallow grooves or notches adjacent to or along each of the end faces 103, 105. These grooves or notches are for receiving a sealing gasket (not shown), which may be a compressible elastomeric plastic, rubber or silicone strip, for example. The sealing gasket may be attached to the end faces 103, 105 in the notches by suitable attachment means, such as screws or adhesives, for example. In some embodiments, such sealing gaskets may be affixed to end parts or faces of the panel 100 without any grooves or notches being formed on or in the panel 100. The sealing gasket is to minimize any noise transmission that otherwise might occur through a small gap between the edge of the panel 100 and the support structure to which the panel 100 is coupled or between adjacent panels positioned end-to-end.
The bottom and top long edge faces 106 and 108 have flat outer edge portions 106a, 106b and 108a, 108b on either side of the recessed portions 107, 109, respectively. The flat outer edge portions 106a, 106b and 108a, 108b may extend a first distance in the thickness direction of the first and second recessed portions from the front wall that is not equal to a second distance in the thickness direction of the first and second recessed portions from the back wall. In other words, the flat outer edge portion 106b that is adjacent the back wall 102 may be shorter or longer in the thickness direction than the length of the flat outer edge portion 106a adjacent the front wall 104 in the thickness direction.
As is shown best in
As is shown best in
Upper and lower front edge faces 106a, 108a are longer than the upper and lower hack edge faces 106b, 408b because the upper and lower hack edge faces 106b, 108b are truncated or cut short by the recessed portions 117 at the first end 111. The upper and lower front edge faces 106a, 108a extend the full length of the panel 100.
Described panel embodiments employ supporting and/or reinforcing structure, for example including one or more rigid supporting elements or components 420, 421, 422 (
The panel 100 has a longitudinal centre-line that may be considered to coincide or lie parallel with a longitudinal axis of the panel 100. In some embodiments, panel 100 may be formed to have a width/height (i.e. distance between top and bottom edge faces 106, 108) different from that shown in
Embodiments of panel 100 may require strong structural integrity in order to be able to withstand high wind loadings, so a fixed rigid support frame 400 (
In some embodiments, the supporting and reinforcing structure comprises a plurality of elongate, generally strong and rigid beams or bars 420, 421, 422, which may be formed of steel or another suitable metal, such as Aluminium, for example. The structure and arrangement of the support frame 400 is shown in further detail in
In at least some embodiments, each panel 100 may be coupled to the support structure only by receipt of elongate bars 420, 421, 422 in respective recesses 107, 109, thus allowing for the plastic shell of the panel 100 to effectively move relative to the support structure, so that the functions and appearance of the support structure and the wall/barrier 500 are relatively unaffected by thermal expansion and/or contraction of the plastic shell of the panel 100 when panels 100 are mounted on support frame 400 as shown in
As shown in
Additionally, the end face 105 of the panel 100 has mating structure to allow the second ends 112 of adjacent panels 100 to nest and mate with each other while remaining physically unattached or not directly attached to each other. Such mating structure may include correspondingly shaped recesses and protrusions, such as a concave recessed portion 105b and convex protruding portion 105a. Such recessed portions 1051) and protruding portions 105a may be relatively shallow in profile, each extending along at least part of the end face 105, and may be protruding or recessed by a maximum of about 5 to 15 mm, for example. When panels 100 are positioned end-to-end with their second ends 112 positioned closely adjacent to each other, and with the front and back walls 104, 102 facing the same direction, the recessed portion 105b is shaped to receive a corresponding protruding portion 105a of the neighbouring panel 100. This mating structure assists in minimising the possibility of gaps being visible in the second ends 112 of adjacent panels 100. For improved sound attenuation purposes, thin sealing gaskets or strips may line parts of the end faces 105 of adjacent panels 100.
Panels 100 may be generally formed to have a substantially hollow interior and be substantially free of sections, portions or structure that join the front and back walls 104, 102, other than at the long edge faces 106, 108 and the first and second ends 111, 112. Such generally hollow panel structures can advantageously allow efficient formation thereof by rotational moulding, without the need for structural supports or thermal communication between the front and back walls 104, 102. Alternatively, as shown and described below in relation to
As shown in
At a lowest position on the vertical beams 410 at which one of the crossbeams 420 is to be coupled, a specific coupling structure 430 is used to couple each end of the beam 420 to a respective vertical beam 410, for example at a flange 416 of the beam 410, as is best illustrated in
For cross-beams 421 that are to be coupled at positions on the vertical beam 410 higher than the lowest crossbeam 420, alternative coupling structure 431 can be employed. Coupling structure 431 is shown in further detail in
At an upper-most position at which an upper beam 422 is to be used to fixedly position the top panel or row of panels 100, a clamping structure 432 is used to affix the upper beam 422 at each end to respective vertical beams 410. The clamping structure 432, may be substantially similar to clamping structure 431 or clamping structure 430.
Lowest crossbeam 420 and upper crossbeam 422 may be sized to be fully or almost fully received within the upper or lower recess 109, 107 of an adjacent panel 100 and such crossbeams may thus be formed of a rectangular hollow section (i.e. metal tube) of lesser cross-sectional thickness compared to the central crossbeams 421 that are required to be simultaneously snugly received within adjacently positioned top and bottom recesses 109, 107 of respective vertically adjacent panels 100.
Referring now to
Some embodiments of panels 100 may employ non-parallel top and bottom edges and longitudinal recesses, for example giving each panel a somewhat trapezoidal appearance, with one end face 103 or 105 being longer than the other, providing such panels can still be tiled with each other to form a wall 500 or wall section 502. Such embodiments may cooperate with correspondingly angled support beams.
Barrier 500 comprises support structure to support the panels 100 in a vertical orientation with the long dimension of the panels 100 extending generally horizontally. The support structure may comprise multiple spaced beams, posts or girders which are anchored to the ground or a suitable alternative anchoring structure in a secure manner in order to lend suitable supporting structure so that large wind forces impinging on the panels 100 are unlikely to displace or perturb the attached panels 100 and wall sections 502. I-beams 410a, 410b and 410c (
As shown in
Clamping structure 431 comprises a clamping plate 470 and a U-bolt 472. Clamping plate 470 and U-bolt 472 are shown in further detail in
Coupling structure 431 is configured to clamp support beams 421 to a flange 416 of an I-beam 410. As is shown best in
As shown in
While gap 622 allows for vertical thermal expansion of the panels 100, a vertically extending gap 633 is also left between adjacent first panel ends 111, as shown in
Referring also to
In some embodiments, a different panel construction may be employed. This different panel construction is shown and described with reference to
An example spacer 1930 is shown in more detail in
Each spacer 1930 has a generally planar web 1931, opposite first and second ends 1932, 1934 and first and second opposed (slightly convex) side portions 1936, 1938, which all-together connect and thereby define the external truss shape that separates the panel walls 1902, 1904 and accommodates the elongate bar 420, 421, 422. The spacer 1930 may, in some embodiments, be formed of a material that is chemically compatible with the plastic material used to form the shell of the panel.
The spacer 1930 may have a length (height) from the first end 1932 to the second end 1934 that is slightly less than the height of the front and back panel walls 1904, 1902 when the panel 1900 is in the upright position shown in
The spacer 1930 may be formed of, or comprise, a plastic material compatible with the plastic material of the panel walls 1902, 1904. For example, the spacer 130 may be formed of a suitable polyolefin, such as a suitable polyethylene or polypropylene material having an appropriate melting point, stiffness and strength for use in a barrier of the type described. In alternative embodiments, the spacer 1930 may be formed of, or comprise, non-plastic materials, such as metals. For example, the spacer 1930 may be formed of, or comprise, light steel or aluminium. Further, the shape of spacer 1930 shown in the drawings and described above may be modified while still performing the same spacing and reinforcement functions as described herein. For example, the spacer 1930 may have side portions 1936, 1938 that have a different, non-convex profile.
The spacer 1930 has opposed flange portions 1943a and 1943b that extend upwardly and outwardly from adjacent the first recess 1941. Each such flange portion 1943a, 1943b has an aperture 1947 formed in a surface thereof to allow coupling of that flange portion 1943a, 1943b to an inwardly projecting flange 1906a, 1906b, respectively of the front and back wall panels 1904, 1902. A suitable fastener may be used to couple the spacer flanges 1943a, 1943b to the wall panel flanges 1906a, 1906b and such a suitable fastener may include a rivet, screw, bolt or clamp, for example. The spacer 1930 has a similar projecting flange arrangement at its opposite end 1934, so that projecting flanges 1944a and 1944b can coupled to lower projecting flanges (not shown in
The web 1931 of each spacer 1930 may have a series of hooked portions 1952 formed thereon to hook on to inversely positioned hooked portions 1952 of a neighbouring spacer 1930, where such spacers 1930 are positioned to act as an end face at adjacent second ends 1912 of panels 1900 that are to be positioned end-to-end. Such hooked portions 1952 can serve to effectively couple such adjacently positioned panels 1900 together. However, coupling structures other than hooked portions 1952 may be employed to similar effect. In particular, the corresponding recessed and mating portions shown and described in relation to
Web 1931 may have a series of apertures 1962 at spaced positions along the length and width of the spacer 1930 in order to reduce the amount of material needed to form the spacer 1930. The spacer 1930 may have an outer peripheral flange 1954 that extends all the way around the outer periphery of the web 1931 to provide additional structural integrity to the spacer 1930. The outer peripheral flange 1954 may extend laterally in one or both directions from the plane of the web 1931.
Some embodiments of panel 1900 may use an alternative spacer 2430 instead of spacer 1930. Spacer 2430 is illustrated in further detail in
Each spacer 2430 defines first and second opposed recesses 2441, 2442, each sized to receive one of the elongate bars 420, 421, 422 and allow the panel 1900 to be held in position by respective elongate bars 420, 421 or 422 that are fixed in position on spaced vertical supports 410. Thus, the spacers 2430 effectively carry the front and back panel walls 1904, 1902 and serve to partly or fully define the top and bottom recessed portions 1909, 1907 that mate with the panel support structure (i.e. cross-beams 420, 421, 422). Some sliding of the spacer 2430 along the elongate bar 420, 421 or 422 may occur during positioning of the panel 1900 on the bar 420, 421 or during any thermal expansion or contraction of the panel walls. Recesses 2441 and 2442 each have a detent 2446, 2447 defined to extend inwardly from the spacer ends and thereby allow a small air gap to be present between the elongate bar 420, 421 or 422 and a bridging section of an end part 2451. This air gap assists to reduce material deterioration that might otherwise occur between the bridging section and the elongate bar 420, 421 or 422.
Each spacer 2430 has a generally similar convex external profile to spacer 1930, including opposite first and second ends 2432, 2434 (having respective first and second end portions 2451, 2452) and first and second opposed (optionally slightly convex) side portions 2436, 2438, which connect and thereby define the external truss shape that separates the panel walls 1902, 1904 and accommodates the elongate bar 420, 421, 422. The spacer 2430 may be formed with end parts 2451, 2452 of a first material, such as a moulded plastic, and side portions 2436, 2438 of a second material, such as a spring steel. If the side portions 2436, 2438 are formed of a flexible material, such as a spring steel, then they may be formed as thin bars having a slight curvature as shown and having a generally uniform thickness and a width of around 10 to 30 mm, for example.
The spacer 2430 may have a length (height) from the first end 2432 to the second end 2434 that is slightly less than the height of the front and back panel walls 1904, 1902 when the panel 1900 is in the upright position shown in
The spacer 2430 has opposed end projection portions 2443a and 2443b that extend longitudinally outwardly from adjacent the first recess 2441 in end portion 2451. Each such end projection portion 2443a, 2443b has an aperture 2467 formed in a surface thereof to allow coupling of that end projection portion 2443a, 2443b to an inwardly projecting flange 1906a, 1906b, respectively of the front and back wall panels 1904, 1902. A suitable fastener may be used to couple the spacer end projections 2443a, 2443b to the wall panel flanges 1906a, 1906b and such a suitable fastener may include a rivet, screw, bolt or clamp, for example. The spacer 2430 has a similar end projection arrangement at its opposite end 2434, so that end projections 2444a and 2444b can be coupled to lower projecting flanges (not shown in
Each of the first and second end portions 2451, 2452 may have one or more apertures 2463 at spaced positions around the respective end portions 2451, 2452 in order to reduce the amount of material needed to form the spacer end portions 2451, 2452.
The convex side portions 2436, 2438 of the spacer 2430 may be coupled to each of the end portions 2451, 2452 by one or more of several different coupling mechanisms, including but not limited to: frictional engagement, interference tit, a snap-fitting, cooperating projections and recesses, adhesives, fasteners or moulding, for example. In the embodiment shown in
For each panel 1900, at least one spacer 1930 or 2430 may be positioned roughly mid-way between the ends 1911, 1912 of the panel 1900. Preferably, at least two more spacers 1930 or 2430 are positioned along the inside of the panel 1900 intermediate the centrally positioned spacer 1930/2430 and each end of the panel 1900. In various embodiments, 2, 3, 4, 5, 6, 7, 8, 9, 10 or more spacers 1930 or 2430 may be positioned inside the panel walls. In some embodiments, the panel 1900 may comprise at least one spacer 1930, for example positioned at one or both ends 1911, 1912, and at least one spacer 2430, for example positioned at positions intermediate the ends 1911, 1912.
Referring now to
The mould plates are formed at 2210 to define a hollow panel when moulded, having a length greater than a width, a thickness less than the width, a front wall, an opposite back wall and opposed first and second long edge regions. The panel shape thus defined has a first end and a longitudinally opposite second end, with the first long edge region defining at least one first recessed portion 107 or 1907 to longitudinally receive and mate with a first longitudinal support structure (beam 420 or 421) and the second long edge region defining at least one second recessed portion 109 or 1909 to longitudinally receive and mate with a second longitudinal support structure (beam 421 or 422).
At step 2220, granules of a suitable polyolefin are added into the mould and the mould is closed tight. The polyolefin granules must be suitable for rotational moulding and may include polypropylene and polyethylene materials, for example. A particularly preferred polyolefin is polyethylene and preferred forms of polyethylene include those that can accommodate pigments and ultra violet radiation stabilizers (i.e. to provide a higher resistance to degradation under exposure to ultra violet radiation). One example of a polyethylene material that can be used is Qenos Alkathene 711 UV. Such polyethylene materials have a generally good chemical resistance to pollutants and can be more readily cleaned of graffiti than other materials, such as stone or concrete panel materials. Panel shells formed of such polyethylene materials may also have an anti-graffiti coating applied thereto, such as a coating provided by APP of Keysborough, Victoria, Australia. Such polyethylene materials are also readily cleanable, for example by a water jet, and do not stain or burn easily. Particular forms of polyethylene that may be suitable include linear low density polyethylene and medium density polyethylene. In some embodiments, high density polyethylene may also be used. In embodiments employing polyethylene or polypropylene as the material for the panel shell, the polyethylene or polypropylene material added into the mould preferably contains suitable additives for UV resistance and/or pigmentation and/or graffiti resistance.
Sound attenuation properties of panels according to described embodiments are designed to meet the requirements of the relevant Australian and/or international standards. For example, attenuation of sound through described panel embodiments may be at least about 25 decibels at frequencies between 250 Hz and 5000 Hz.
At step 2230, the panel 100 is formed using conventional rotational moulding techniques, including heating the mould while rotating it around two different axes of rotation so that the polyolefin granules melt and accrete on the inside surfaces of the mould plates. This heating and rotation is performed for a set period of time, following which the mould is cooled and then, at 2240, the formed panel is removed from the mould.
For formation of panels 1900, the panel shell formed at steps 2210 to 2240 may be cut at 2250 to separate front and back wall panels from each other and thus form the front and back wall panels 1904, 1902 as shown in
As part of the cutting step 2250, the original walls along top and bottom edge faces 108, 106 that define the top and bottom recesses 109, 107 may be at least partially cut away, with the result that the longitudinally extending recesses 1907, 1909 are instead formed by an open channel defined in part by the recesses 1941 and 1942 of the spacers 1930 (or recesses 2441 and 2442 of spacer 2430) positioned at locations along the length of the panel 1900. In between the positions of the spacers 1930 or 2430, the top and bottom longitudinal recesses 1909, 1907 are effectively defined by an open gap between the front and back walls 1904, 1902.
At 2260, the spacers 1930 or 2430 (or a combination thereof) are inserted and connected in a vertical bridging orientation between the front and back panel walls 1904, 1902 using suitable connection means, such as rivets, to form the panel 1900 in the manner illustrated in
The method 2200 may be used to form panels of varying sizes, shapes and configurations, but for longer panels and particularly those panels over about three metres in length, each panel may have some form of reinforcing structure, for example in the form of metallic reinforcing elements or other non-metallic strengthening, stiffening or reinforcing structure.
While described embodiments are considered to be particularly suitable for sound attenuation barriers, some embodiments are directed more generally to wall panels that can be used in different ways. For example, described embodiments may be used as panels for cladding of buildings or to form an exterior face or design on a building, since they are light, easily transportable and can be readily customised. Further, rotational moulding of such panels can provide significant advantages over traditional concrete panel forming.
A further advantage of panel embodiments described herein is that they are formed of a recyclable plastic that can be readily separated from associated reinforcing of support structure for recycling, if desired.
Referring also to
At step 2330, the panels are coupled to the support structure to form a wall. As described previously, such panels may be used to form a sound attenuation barrier 500 or 1500, with multiple wall sections 502, 1502. Alternatively, the wall may not be intended to function solely as a sound attenuation barrier and may form part of a building structure, such as cladding or an exterior pattern or surface of a building. The coupling of the panels at 2330 to the support structure may be as previously described, for example using coupling structure 430, 431.
Once the lowest crossbeam 420 is affixed at 2315, the panels 100 or 1900 can be positioned on the lowest cross bar and the next cross bar 421 can be positioned to be received within the recess 109 or 1909 to hold the lowest one or plural panels 100 or 1900 in place. Step 2230 thus involves sequentially locating panels on top of a cross bar and securing them in position by locating another cross bar in the longitudinal recesses across the top of the panel until the desired number of rows of panels have been put in place.
Reference is also made to
Embodiments have been described generally herein by way of non-limiting example. Thus, this detailed description should be taken as illustrative and not restrictive, taking into account that some variation or modification of the described embodiments is possible without departing from the spirit and scope of the invention or inventions described herein.
It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the above-described embodiments, without departing from the broad general scope of the present disclosure. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive.
Number | Date | Country | Kind |
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2013273747 | Dec 2013 | AU | national |
This application is a continuation of U.S. patent application Ser. No. 15/104,920, filed on Jun. 15, 2016, which is a United States national stage application under 35 U.S.C. § 371 of PCT Application No. PCT/AU2014/050432 designating the United States, filed on Dec. 18, 2014, each of which is hereby incorporated by reference in its entirety, and PCT/AU2014/050432 claims priority to Australian Patent App. No. 2013273747, filed on Dec. 20, 2013.
Number | Date | Country | |
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Parent | 15104920 | Jun 2016 | US |
Child | 16569231 | US |