The present invention relates to a wall seal system and, more particularly although not exclusively, to such a system suited to, although not exclusively, the flexible seal of adjacent concrete panels. More particularly, although not exclusively, the system is suited to situations where concrete panels are utilised to provide a reinforced wall structure in civil works, particularly earthworks.
There are many civil works scenarios where wall structures are required. In some instances these wall structures are made as mounds of self supporting material. In other instances the wall structure boundary is defined by and supported by a multiplicity of substantially vertically disposed concrete panels. The concrete panels allow much steeper wall definition boundaries then mounds of self-supporting material can usually provide. Where concrete panels are used in these situations there arises the problem in some instances of requiring that the resulting wall should be substantially impermeable to the passage of water of like liquids of fine solids such as sand or soil therethrough. This requirement can apply to liquid flow in a direction from within the wall structure to external the wall structure or vice versa.
As one might expect in civil works there can be movement of the wall structure over time. More particularly there can be movement of adjacent panels with respect to each other. This presents a problem to providing reliable seal of the gaps between the panels.
WO2013/057299 to Alphaplan International discloses use of the thermosetting polymer resin as a seal between adjacent panels. Its stated virtue is its hardness. Such an arrangement is not flexible and not at all suited to situations where there is movement between adjacent panels.
FR2415693 to Bachy likewise discloses a seal system for vertical joints between abutting concrete panels in which the seal members are partially embedded in the panels to emerge at niches at the corners of the panels. There corner niches form a confining channel when the panels are in situ making it difficult to heat weld a strip over the ends of the seal members, or even more difficult, welding the overlap of one of the members over the other. Other disadvantages of the Bachy arrangement arise in that firstly, the filling in of the channel after welding prevents access to the seal for inspection and secondly, allows for virtually no flexibility of movement between the panels.
It is an object of the present invention to address or at least ameliorate some of the above disadvantages.
The term “comprising” (and grammatical variations thereof) is used in this specification in the inclusive sense of “having” or “including”, and not in the exclusive sense of “consisting only of”.
The above discussion of the prior art in the Background of the Invention, is not an admission that any information discussed therein is citable prior art or part of the common general knowledge of persons skilled in the art in any country.
Accordingly, in one broad form of the invention there is provided flexible seal system for provision of a substantially watertight seal between adjacent concrete panels; said system comprising:
a first flexible seal member having an anchor component and an overlap component; and
a second flexible seal member having an anchor component and a surface component;
wherein the overlap component of the second flexible seal member is structured and selected in use to overlap the surface component of the second flexible seal member sufficient to permit welding of at least a portion of said overlap component of said first flexible seal member to at least a portion of said surface component of said second flexible seal member so as to form a continuous welded seal between and along the length of said first flexible seal member and said second flexible seal member.
Preferably, the length of the first flexible seal member and the second flexible seal member is a longitudinal length.
Preferably, the first flexible seal member is homogeneous.
Preferably, the second flexible seal member is homogeneous.
Preferably, the first flexible seal member is cast into a concrete panel by immersing its anchor component into at least a surface region of the concrete panel prior to the setting of the concrete from which it is formed.
Preferably, the first flexible seal member includes a surface component.
Preferably, the anchor component comprises a projection extending from the flexible seal member.
Preferably, the projection includes a bulbous portion or enlarged angular portion at a free edge thereof.
Preferably, the flexible seal member extends substantially around the entire periphery of each concrete panel.
Preferably, the anchor component comprises a substantially continuous extension, extending substantially, continuously, longitudinally, for the length of the flexible seal member.
Preferably, the anchor component comprises a substantially discontinuous, periodic extension, extending substantially, longitudinally, for the length of the flexible seal member.
Preferably, individual panels are one or more of square, rectangular, or cruciform.
Preferably, the panels are of dimension one-meter by one-meter or six-meter by six-meter or six-meter by one-meter.
In a particular preferred form, the panels are precast panels.
In an alternative preferred form, the panels are cast in situ.
In another broad form of the invention, there is provided a method of constructing a substantially waterproof wall from concrete panels; the method comprising the steps of
In yet another broad form of the invention, there is provided a method of reclamation of landfill volume comprising substantially vertical wall structure for an inclined beam.
Preferably, the substantially vertical wall structure is constructed according to the method of constructing a substantially waterproof wall from concrete panels described above.
Preferably, the substantially vertical wall structure is constructed from concrete panels.
Preferably, the concrete panels are sealed according to any of the seal systems described in this section of the specification.
In yet a further broad form of the invention, there is provided a method of landfilling comprising the steps of:
Preferably, the concrete panels are sealed utilising any of the seal systems described in this section of the specification.
In yet a further broad form of the invention, there is provided a flexible seal system for provision of a substantially watertight seal between adjacent concrete panels; said system comprising:
a first flexible seal member having an anchor component and a surface component;
a second flexible seal member having an anchor component and a surface component; and
a overlap component;
wherein the overlap component is structured and selected in use to overlap the surface component of the first flexible seal member and the second flexible seal member and the second flexible seal member so as to form a continuous welded seal between and along the length of said first flexible seal member and said flexible seal member.
Preferably, the length of the first flexible seal member and the second flexible seal member is a longitudinal length.
Preferably, the first flexible seal member is homogeneous.
Preferably, the second flexible seal member is homogeneous.
Preferably, the first flexible seal member is cast into a concrete panel by immersing its anchor component into at least a surface region of the concrete panel prior to the setting of the concrete from which it is formed.
Preferably, the first flexible seal member includes a surface component.
Preferably, the anchor component comprises a projection extending from the flexible seal member.
Preferably, the projection includes a bulbous portion at a free edge thereof
Preferably, the flexible seal member extends substantially around the entire periphery of each concrete panel.
Preferably, the anchor component comprises a substantially continuous extension, extending substantially, continuously, longitudinally, for the length of the flexible seal member.
Preferably, the anchor component comprises a substantially discontinuous, periodic extension, extending substantially, longitudinally, for the length of the flexible seal member.
Preferably, individual panels are one or more of square, rectangular, or cruciform.
Preferably, the panels are of dimension one-meter by one-meter or six-meter by six-meter or six-meter by one-meter.
In preferred forms, the panels are shaped.
In a particular preferred form, the panel is arched.
Accordingly, in a first broad form of the invention, there is provided a method of forming an irrigation or other liquid conveying channel; said method including the steps of:
Preferably, said first flexible seal member comprises said surface component proximate a first edge of said concrete panel; said surface component extending over a portion of the surface of a said concrete panel; said first flexible seal member further comprising said overlap component extending from said surface component so as to extend beyond said first edge, said anchor components projecting from said surface component and embedded in said concrete panel.
Preferably, said second flexible seal member comprises said surface component proximate a second edge opposite said first edge of said concrete panel; said at least one anchor component projecting from said surface component and embedded in said concrete panel.
Preferably, wherein each said surface component is retained against said surface of said concrete panels by two said anchor components embedded in the concrete or said concreted panels; each said anchor component comprising a leg portion projecting from respective said surface components; said leg portion generally normal to said surface component; said leg portion terminating in a wider edge portion; said leg portion and said wider edge portion extending substantially along the length of said anchor component.
Preferably, said surface component, said overlap portion and said at least one anchor component of said first flexible seal member from an integral first polymer structure; said surface component and said at least one anchor component of said second flexible seal member forming an integral second polymer structure.
Preferably, each of said opposing walls is erected as to at least two horizontally arranged rows of abutting concrete panels; the number of rows defining the depth of said channel; said flexible seal members adapted to seal vertical joints between said abutting panels in each row and horizontal joints between panels of superior and inferior rows.
Preferably, each said concrete panel is provided with said first and second flexible seal members proximate respective ones of a first opposing pair of edges of said panel and proximate respective ones of a second opposing pair of edges of said panel.
Preferably, said method includes the further step of welding an overlap component of a said first flexible seal member proximate a vertical edge of a first said concrete panel, to a surface component of a said second flexible seal member proximate an adjacent vertical edge of an abutting second concrete panel to form a watertight seal between said abutting concrete panels.
Preferably, said method includes the further step of welding an overlap component of a said first flexible seal member proximate a horizontal edge of a said concrete panel of a superior row of concrete panels of said wall to a surface component of a second flexible seal member proximate a horizontal edge of an adjacent concrete panel of an inferior row of concrete panels of said wall.
Preferably, said method includes bending overlap components of said first flexible seal members at lower edges of lowermost ones of said concrete panels of said twin opposing walls of concrete panels, to extend over a portion of a bottom surface of said ditch, a liner element then laid along said bottom portion over said overlap portions being welded to said overlap portions so as to form a watertight seal between said twin opposing walls.
Preferably, each said panel is anchored into back-fill soil behind said panel by means of at least one tie back element in said soil; said at least one tie back element extending rearward from each said panel.
Preferably, each wall of said irrigation channel extends above a surface level of said back filled soil adjacent each said wall.
Preferably, said opposing walls of said channel are erected as abutting vertical concrete panels; vertical length of said vertical concrete panels defining the depth of said channel; said flexible seal members adapted to seal vertical joints between said butting vertical concrete panels.
Preferably, said abutting vertical concrete panels of said opposing walls are supported in transverse spacer elements laid along the bottom of a prepared trench at intervals equal to width of said abutting vertical concrete panels; lower edges of said abutting vertical concrete panels retained in grooves formed in opposite ends of said spacer elements, and wherein similar spacer elements engaging upper edges of said abutting vertical concrete panels act to form a controlled structure, with generally parallel vertical walls.
Preferably, said method includes the further step of welding an overlap component of a said first flexible seal member proximate a vertical edge of a first said vertical concrete panel, to a surface component of a said second flexible seal member proximate an adjacent vertical edge of an abutting second vertical concrete panel to form a watertight seal between said abutting concrete panels.
Preferably, each said abutting vertical concrete panel is provided with a second flexible seal member proximate a lower horizontal edge of said concrete panel.
Preferably, lengths of polymer material are laid along the bottom of said trench; opposing edges of said polymer material folded upwards to overlap at least a portion of each surface component of said second flexible seal member at said lower horizontal edge of each of said concrete panels; said opposing edges of said polymer sheets welded to said surface component to form a watertight seal between said polymer sheets and said vertical concrete panels.
In another broad for of the invention, there is provided a method of forming concrete panels provided with joint flexible seal members for walls for an irrigation or other liquid conveying channel; said method including the steps of:
In still another broad form of the invention, there is provided a wall for an irrigation channel of other liquid controlling structure; said wall formed of rows of abutting concrete panels stacked one on top of another to form a substantially vertical array of said panels; each said panel provided with first and second flexible seal members arranged to overlap horizontal joints between vertically abutting panels and vertical joints between horizontally abutting panels; an overlap component of a said first flexible seal member proximate a lower horizontal edge of a panel of a superior panel, welded to a surface component of second flexible seal member at an upper horizontal edge of a vertically abutting inferior panel, and
an overlap portion component of a said first flexible seal member proximate a first vertical edge of each said panel welded to surface component of a second flexible seal member at a second vertical edge of a horizontally abutting panel; said overlap component extending from a surface component of said first flexible seal member; and wherein respective surface components of each said first and said second flexible seal members are provided with anchor components embedded in concrete of said concrete panels.
Preferably, each said concrete panel is provided with a first flexible seal member along each of a first pair of contiguous edges and with a second flexible seal member along each of a second pair of contiguous edges.
In still another broad form of the invention, there is provided a panel of settable material for use in walls and other barrier structures; said panel provided with at least one first flexible seal member along one edge of said panel and at least one second flexible seal member along an adjacent edge of said panel; said first flexible seal member comprising a surface component extending over a portion of a surface of said panel and an overlap component extending from said surface component; said second flexible seal member comprising a surface component extending over a portion of said surface of said panel, wherein each said surface component is retained over said surface of said panel by at least one anchor component projecting from a respective said surface components into said settable material and, wherein said overlap component of said first flexible seal member of a first said panel is configured to overlap at least a portion of a second flexible seal member of a second said panel when said first and second panels are in an abutting relationship.
Preferably, said settable material is concrete.
Preferably, said panel is provided with one said first flexible seal members along each of two adjacent edges of said panel.
Preferably, said panel is provided with one said second flexible seal member along each of two adjacent edges of said panel.
Preferably, said panel is provided along a first two adjacent edges with said first flexible seal members and further provided along a second two adjacent edges with said second flexible seal members.
Preferably, said anchor components project from said surface components substantially at right angle into said settable material; each said anchor component comprising a leg or elongate flange ending in an enlarged portion.
Preferably, ends of said surface portions of respective said first and said second flexible seal members are mitered at their outer ends; mitrered edges of said flexible seal members fusion welded one to another to form a continuous seal surface proximate the periphery of said panel.
Preferably, said overlap component of a said first flexible seal member of one said panel is fusion or heat welded to a surface component of a second flexible seal member of an abutting said panel.
Preferably, said first and said second flexible seal members provide for impervious seals of horizontal and vertical joints between rows and columns of said panels when constructed as a barrier wall.
Preferably, said panels are arranged in said barrier wall so that abutting edges of said panels are respectively provided with a first and a second flexible seal member.
Embodiments of the present invention will now be described with reference to the accompanying drawings wherein:
The present invention is drawn to a flexible seal system for sealing the joints between abutting concrete (or other settable material) panels. In each of the below described embodiments, each panel is prepared when cast with a flexible seal members of two distinct configurations; a first flexible seal member and a second flexible seal member. Both the flexible seal members include at least one anchor component embedded within the concrete and a surface portion which extends over, or overlays, a portion of the outer surface of the panel. The first flexible seal member is distinguished from the second flexible seal member in that an overlap portion extends from its surface portion in such a way that the overlap portion extends beyond the edge of the panel.
With reference to
The flexible seal system 10 further comprises a second flexible seal member 17, disposed proximate a second end of an abutting concrete panel 12, comprising, in this instance, a surface component 18 extending over a portion of the surface region 20. Second flexible seal member further includes an anchor component 19 in this instance in the form of a first leg 19A and a second leg 19B projecting preferably substantially at right angles from surface component 18. The legs 19A and 19B are cast into the surface region 20 of second concrete panel 12 in such a way as to anchor surface component 18 reliably into the second concrete panel 12 whilst leaving surface component 18 exposed above surface region 20.
The flexible seal members are arranged so that each concrete panel is provided with a first flexible seal member along each of a first pair of contiguous edges and with a second flexible seal member along each of a second pair of contiguous edges. Thus the differences between the first and second flexible seal members provides, in this embodiment, for scaling around both the vertical and horizontal edges of the panel.
As shown in the plan view of a concrete panel 11 prepared with the flexible seal system of the invention in
The concrete panels of this preferred embodiment may be formed as follows. The flexible seal members are prepared in lengths to suit the dimensions of the panel to which they are to be applied and the ends mitered as described above. The first and second flexible seal members are then welded at their intersections to form the continuous seal surface and relative the formwork so as to become embedded within the concrete, and leaving the surface components extending over the surface. One the concrete has set, pressure testing of the flexible seal members completes the process.
Each of the first and second flexible seal members comprises an integral polymer structure. In use the first concrete panel 11 and the second concrete panel 12 are juxtaposed in sufficiently close relationship that overlap component 16 or at least a portion of it overlaps a longitudinal length of at least a portion of the surface component 18 as shown in the plan view of
It should be noted that the surface component extending along an outer surface of the concrete panel with the overlap portion disposed as shown in
The overlap component 16 and surface component 18 are made from a weldable plastics material whereby, following the juxtaposition of the adjacent panels the overlap component 16 is welded along its length to the surface component 18 by means not shown. Preferably, the overlap component of the first flexible seal members is of thinner or more pliable than the anchor components.
Preferred materials for the flexible seal members 13, 17 include plastics materials, in particular, plastic materials which have the capacity to stretch and flex and preferably to be welded one to the other.
Suitable materials include polymers; HDPE; PVC; Teflon and polymer blends. Preferably these materials may be particularly selected and optimized for properties such as elongation, resistance to chemicals, and resistance to heat. Polyethylene and polypropylene are particularly suited for petrochemical applications. PVC of PET may be suited to water applications.
Preferably the same material is used for both the first flexible seal member 13 and the second flexible seal member 17 thereby to assist in homogeneity of the weld (see below).
A preferred process of welding is thermal fusion welding utilising a modified plastics extruder machine (not shown) that can be hand operated and which extrudes a molten bead of High Elongation resin through a “stepped” die head over an overlapping weld zone 21. Preferably the weld zone 21 is prepared via abrasion prior to extrusion welding to remove surface grit and contamination.
In preferred forms the weld consumable comprises the same material composition as that of the first flexible seal member 13 and second flexible seal member 17. At
Preferably, each weld is tested for water tightness at the completion of the weld. In a preferred method, after preparing the seal to be tested with a suitable liquid, a plexiglass dome, provided with a seal around its periphery, is placed over the area to be tested and a partial vacuum created under the dome to show up any imperfections. This testing is facilitated by the ready access available to the overlap component of the first flexible seal member and the bead of welding along the overlap edge.
With reference to the wall panel plan view of
Typical precast concrete panel or cast in situ panel dimensions can be of the order of 1870 mm×2170 mm or as required by the application. The panels themselves may be square, rectangular, cruciform, arched or other suitable shapes preferably adapted for adjacent abutting of long edges thereof.
In preferred forms the flexible seal members are applied on the “inside” of the resulting barrier structure. That is to say on the side abutting the material or liquid which is being retained by the structure.
With reference to
The overlaps of the arrangement of
With reference to
As shown in
The wall panel arrangement of
In addition, in respect of any one of the above described embodiments, a fire-resistant/heat-resistant/chemical-resistant/UV-resistant expandable and/or flexible sealant or mastic may be inserted in the gap region between adjacent panels. In some forms this will be for the purpose of providing UV resistance. In other forms it will be for the purpose of providing heat resistance. In some forms this will be particularly for protecting the welded flexible seal.
Reclamation System
The above described system can be utilised as part of methodology to reclaim landfill volume.
With reference to
An alternative arrangement which permits use of substantially the volume of the berm involves use of a substantially vertical wall structure 51 thereby permitting use of volume 52 that otherwise would be occupied by the berm itself.
Advantageously, the vertical wall structure 51 is constructed utilising the arrangements described with references to the earlier embodiments of
With references to
In some applications a liner may be applied to the filling area 60. In some applications a contiguous liner may be applied over the inside face of the wall structure 63, 65.
Applications for embodiments of the invention described above include, but not are limited to:
In a preferred arrangement in which the concrete panels with the flexible seal system of the invention are used for sequential erection of a wall defining the boundary of the refuse land fill, the concrete panels are erected with the flexible seal members on the rear surface of the panel, that is away from the refuse land fill. In this arrangement, the flexible seal member along the lower horizontal edge of the lowermost or first row of panels of the wall, is the second flexible seal member described above and designated 17 in
With reference to
In this instance, the overlap component 416 comprises a separate component from the first flexible seal member 413 and the second flexible seal member 417. Accordingly, in use, the adjacent wall panels 411, 412 are juxtaposed and then the overlap component 416 is applied so as to overlap at least a portion of both the first flexible seal member 413 and the second flexible seal member 417, and substantially along the entire length thereof. The overlap component 416 is then welded to both flexible seal members 413, 417.
This embodiment is suited for use in most situations where the previously-described embodiments are applicable.
In this preferred embodiment of the invention, wherein like components are numbered as for earlier embodiments, except the 500 series, the panels described above are arranged to form an irrigation channel 500 as shown in the cross section view of
With references now to
Depending on the desired depth of the channel to be constructed, and on the size of the panels to be employed, a number of panels 520 are arranged stacked one on top of another to a level at which the twin opposing vertical walls 524 and 526 extend above the level of the adjacent ground surface 534. The panels may be stacked in vertical alignment or may be staggered by a proportion of their length. Preferably the walls extend a meter above the surface, or to a level where access to the channel by wild and feral animals is prevented.
As described above, the flexible seal members anchored in each of the panels, are arranged so that a first flexible seal member of the type labelled 513 (13 in
Panels 520 are further provided with complementary flexible seal members at their vertical edges and the panels positioned such that a flexible seal member 513 is adjacent to a flexible seal member 518. Thus similarly, the vertical joints between longitudinally abutting panels may also be sealed by the welding of the overlapping portion of flexible seal members 513 to flexible seal members 518.
The overlap portions of the first flexible seal members 518 of the lowermost panels 336 and 338 of each of the walls, may be bent and laid against surface of the bottom 340 of the channel as shown in
It can be seen that the method of construction of irrigation channels by means of the panels of the invention provides a number of advantages over conventionally constructed channels. Firstly the panels are easily and rapidly erectable, especially, if in a preferred form, cast in low density concrete. Secondly the cast-in flexible seal members provide a simple and effective means of making the joints between abutting panels watertight. Furthermore the overlap components of the flexible seal members at the lower edges of the lowermost pane provide a unique element for the welded attachment of a liner for the bottom of the channel. Finally, the relatively narrow surface area to depth of the channel minimises water loss through evaporation.
With reference now to
Panels 610 are located in spacer elements 612 laid along the bottom of a prepared trench at intervals equal to the width of the panels 610. The lower edges 614 of the panels 610 are retained in grooves 616 formed in the ends of the spacer elements 612. Similar spacer elements 618 are located along the upper edge 620 of the panels 610 to form a controlled structure, with generally parallel vertical walls.
Sealing along the vertical joints 608 between adjacent panels 610 is by means of the first and second configured flexible seal members described above, with the overlap component 622 of the first configured flexible seal member of one panel, welded to the surface portion of the second configured flexible seal member 624 of the adjacent panel. Usually, though not necessarily, the panels 610 will be erected with the first and second flexible seal members directed to the inside of the irrigation channel as shown in
Panels 610 of this preferred embodiment are provided proximate their lower edges with a flexible seal member 626 of the form described above as the second configured flexible seal member. That is, a flexible seal member extending across the width of the panel 610 and comprising a surface component from which project at least two anchor components embedded into the concrete of the panel.
The bottom of the channel 600 may be formed of a sheet 628 of polymer material compatible with that of the flexible seal members of the panels. These sheets forming the base of channel are formed or folded into a channel form with upturned flanges 630 which are then welded to the flexible seal members (not visible) along the lower edges of the panels. The sheets are of a length to overlap the width of the panels (as well as the spacer elements) so that the edge of an overlap of one sheet may be welded to the surface of the next adjacent sheet. Alternatively, the sheet 628 may be of sufficient length to extend past a number of panels 610 and spacer elements 612.
By these means, the vertical joints between panels 610 and the bottom of the channel 400 are rendered water tight by the welding of various flexible seal members and bottom sheets.
In some applications it may be desired to clad the bottom of the channel with concrete slabs extending between adjacent spacers so as to provide a protective floor over the polymer sheets. By this means for example, mechanical equipment may be used to clean the channel from sediment and accumulated debris.
The construction method illustrated in
In at least one preferred embodiment, the panels 610 are provided proximate their upper edges 620 with first flexible seal members as described above. The channel may then be covered over with panels provided on their undersides with flexible seal members according to the invention to which the overlap components of the flexible seal members of the vertical panels may be welded. Thus the channel in this embodiment may become a fully sealed conduit or tunnel for the movement of liquids under some pressure.
Although the above embodiments are drawn to an irrigation channel, it will be appreciated that the panels and wall seal system of the invention may be applied to other liquid conveying channels such as storm water channels for example. It will further be appreciated that although the above described panels are planar, the flexible seal members of the invention may equally be applied to the edges of curved panels to form arched structures.
In one arrangement the panels and seal system of the invention may be adapted for the construction of a tunnel for conveyance of cabling or traffic for example. In this case the vertical and horizontal panels are arranged with the flexible seal members on the outward surfaces of the panels to make the joints between panels proof against external hydraulic pressure.
In yet a further embodiment of the invention, the seal system may be applied to the seal of tunnels formed of curved panels to form arches as shown in
The curved panels 710 for the tunnel 700 of
In use, as shown in
Alternatively, as also shown in the detailed view of
In an alternative arrangement of a tunnel sealed with the seal system of the invention, a tunnel 800 as shown in
In this arrangement in which each arch unit comprises a pair of curved panels 810, 811 the pairs are arranged with flexible seals as shown in
As illustrated in cross section in
Embodiments of the invention as discussed above may be applied with advantage to concrete tank reservoirs and also to concrete building structures where the concrete construction may be either of the pre-cast or in situ type.
In one further arrangement of the seal system according to the invention, the system may be applied to bund walls for dams. In this instance the bund walls may be formed of vertical concrete panels as described above. Sealing between the panels is provided with the same first and second flexible seal members arranged at the edges of adjoining panels.
In a further preferred arrangement, the seal system of the invention may be applied in the construction of the walls or tanks in a tank farm. In this case vertical panels are arranged to form either rectangular or circular enclosures with the vertical joints between abutting panels sealed by the first and second flexible seal members. The base of a tank so formed may comprise a sheet of compatible material which can be thermal fusion welded to the flexible seal members at the lower edges of the vertical panels to form a watertight tank enclosure.
Number | Date | Country | Kind |
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2013206618 | Jun 2013 | AU | national |
2013263720 | Nov 2013 | AU | national |
This application is a continuation of application Ser. No. 14/901,478 filed on Dec. 28, 2015, which is a 371 of international Application PCT/AU2014/000667 filed on Jun. 27, 2014, which claims the benefit of Australian Applications Numbers 2013263720 filed Nov. 26, 2013 and 2013206618 filed Jun. 28, 2013, which designated the U.S., the entire contents of each of which are incorporated herein by reference.
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Number | Date | Country | |
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20180216341 A1 | Aug 2018 | US |
Number | Date | Country | |
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Parent | 14901478 | US | |
Child | 15936864 | US |