TECHNI CAL Fl ELD

The present invention relates to components for a fence panel, components for gates, a fence panel assembly itself, and a gate assembly. The fences are for enclosing and/or dividing garden spaces and the like, while the gates are for providing access between, to and from, fenced areas. In particular applications, the invention relates to a modular fence panel assembly able to interconnect with like modular fence panels. In other applications the invention relates to modular gate panels.

BACKGROUND

Fences are used to mark the boundary of a property and to provide privacy for persons within the boundary. Gates provide access to and from fenced areas.

A known fence type comprises a series of planar fence infill panels disposed between upright posts set into the ground. For example, concrete posts may be embedded in the ground at spaced apart intervals; wooden panels would be secured between spaced-apart posts. The fence panels may be produced from a wide range of materials, including wood, metal or plastics, and are selected according to usage environment, desired aesthetic and cost.

Modular fence panel assemblies are known and each one typically comprises a pair of posts and a plurality of slats. In order to construct the modular fence panel, the posts are first secured to the ground or an existing upright post, and the slats secured therebetween. Each post may include a plurality of apertures spaced therealong for receiving the slats, and each slat is inserted into an aperture in each post. This kind of modular assembly allows a fence panel to be cost effectively manufactured and conveniently packaged in a kit of parts (known as 'flat packed'), but it is common for such an assembly to suffer from a number of drawbacks. For example, a modular fence panel assembly can lack rigidity and therefore be damaged or deformed by strong winds. This lack of durability is not only unnecessarily costly but can also negatively impact upon security for the property. Furthermore, known fence panel assemblies are often unattractive and considered unsuitable for high value properties.

Known slats and fence panel assemblies themselves can be difficult and time consuming to assemble on site. Furthermore, the slats and fences can lack flexibility during the assembly process, such that the fence can take longer than anticipated and sometimes does not fit the envelope intended.

Known gates tend to sag over time and are also difficult and time consuming to assemble, and can require a high degree of manual skill. Known gates can also lack flexibility in the assembly process, such that in many cases they do not fit in the intended envelope.

Known slats themselves in a modular fence panel can lack rigidity and/or beauty.

Accordingly, the present technology seeks to provide a solution that ameliorates at least one of the disadvantages present in the prior art, or which provides another alternative to the prior art approaches.

SUMMARY

In one broad form the present technology provides an elongate slat for a fence panel module which has one or more recesses, projections, or elements disposed along its long sides for coupling with other elongate slats. The recesses or projections or elements can be fastening elements attached to, or integral formations along, the sides. In another broad form the present technology provides a fence panel module which includes one or more elongate slats releasably fastened at their ends in apertures on opposed posts. The fastening arrangement is such that there is at least one quick release fastening element substantially disposed within the post, configured to hold at least one of the slats against a portion of the post.

According to one aspect of the present invention there is provided an elongate slat for a fence panel module, the elongate slat including

opposed long sides extending between opposed first and second ends, and

one or more recesses or projections or elements disposed along at least one of the opposed long sides for use in coupling with other elongate slats.

In one embodiment the opposed long sides are disposed along the sides of slat faces.

In one embodiment the coupling elements are brace members as described herein.

In one embodiment a projection in use cooperates with another projection by use of an intermediate element. In one embodiment the intermediate element is a spacer with apertures for receiving two coupling elements, one at each end.

In one embodiment the spacer includes a rebate or relief at one end to relieve one wall to allow a coupling formation into the end via the rebate in the side wall. In accordance with one aspect of the present invention there is provided a spacer with a rebate cut or relief in one wall so that a projection may be introduced into the end of the spacer from one side. Preferably the spacer includes a central aperture. Preferably the central aperture is of non circular cross section so that the spacer cannot rotate about its central axis. In one embodiment the recesses or projections or elements are coupling formations disposed into each of the opposed long sides, such that a first coupling formation on one side is formed to cooperate with a second coupling formation on the other long side, such that when the elongate slats are stacked one atop the other, the one or more cooperating coupling formations on the long sides couple with one another for support of the slats along the long side.

The first and second coupling elements may each include a coupling recess open at an outer end. One recess may be slightly narrower than the other so that one coupling element may fit at least partially within the recess of the other.

In one embodiment the first and second coupling recesses include one brace arm so as to define one wall of the recess. The brace arm of one coupling recess may have a notch or rebate or tab so as to fit with a brace arm of the other coupling recess to couple therewith.

In embodiments the coupling elements are configured to receive a reinforcing element in the recess for strengthening the slats against forces normal to the slat. The reinforcing element could be a bar or cylinder or batten of about the same cross-section as the recess, to couple and strengthen the recesses together. This arrangement works generally because the slats are inhibited from vertically separating when installed.

In embodiments the coupling elements on opposed faces are identical and abut along open edges so as to provide a substantially seamless join. In use there is no interengagement of abutting coupling elements in those embodiments (without a reinforcing bar disposed in the recess), but the brace arm still provides some increased strength against forces normal to the slat.

In one embodiment the elongate slat includes a planar face. In some embodiments the elongate slats have acoustic attenuation elements. In one embodiment the acoustic attenuation formations include profiles on the faces.

In one embodiment the profile on the elongate face could run transversely across the slat (between the long sides) or longitudinally along the slat (between the ends) or a combination of both.

In these embodiments the profile is sinusoidal. In other embodiments the profile is sawtooth, square-wave, or includes local spots and depressions, or indeed, the profile could be any kind of profile, being an impression of an animal, fish, person, abstract pattern or like profile. The profile may provide sound absorbing properties.

In some embodiments the acoustic attenuation elements are cuts in the faces of the elongate slats. In some embodiments the cuts are disposed along the length, but in most cases the cuts will be a pattern or picture in a tryptich or quartich form, or generally polyptych, disposed across multiple elongate slats.

In one embodiment the elongate slat is a single-walled element. In some embodiments the slat is a rectangular or square hollow section. In embodiments the elongate slat is extruded from aluminium or plastic but in some embodiments it may suit an application to be roll-formed or press- braked from a flat sheet of steel or other suitable material.

According to one aspect of the present invention there is provided a fence post including:

at least one slat-receiving opening on one face for receiving at least a portion of an elongate slat therein;

a quick-release fastener disposed substantially within the post and configured to turn about an actuation axis so as in use to hold an elongate slat against a portion of the slat-receiving opening. According to one aspect of the present invention there is provided a fence panel assembly comprising:

a plurality of elongate slats;

a pair of posts, each post having at least one slat-receiving opening on one face; and

a quick-release fastener disposed substantially within the post; wherein the plurality of elongate slats extend between the slat- receiving openings on the posts.

In one embodiment there is a single slat-receiving opening which extends along the post from a top to a bottom. The post in this embodiment is in the form of a channel. The channel may be extruded or folded, or rolled.

In one embodiment the channel has an opening in a centre of the face.

In one embodiment the quick release fastener includes a fastener element which is cam-shaped or generally non-circular in cross-section so that it needs only to be turned about an actuation axis less than one full rotation to move between a free position and a fastened position. In one

embodiment the cam is an ovoid shape.

For example, if the fastener element was ovoid in shape, it would only need to be turned less than 90° to move between the unlocked position, and the locked position.

In one embodiment the post includes a following recess for guiding the fastener element between the unlocked and the locked positions.

In one embodiment the following recess includes an elongate aperture generally shaped as an inverse to that of the ovoid cam. According to another aspect of the invention there is provided a fence panel assembly comprising a plurality of slats, a pair of posts, each post having a plurality of apertures extending therein, each aperture dimensioned to receive one of the slats, a pair of rails, each rail having an engaging portion at each end thereof, the engaging portion dimensioned to fit within an aperture, and a plurality of connectors, each connector adapted to engage one of the engaging portions, wherein each of the plurality of slats and rails are arranged between the pair of posts and received in one of the apertures, and wherein each connector engages a respective engaging portion.

In accordance with one aspect of the present invention there is provided a method of assembly of a fence panel, the method including the steps of:

Inserting a slat or slat assembly into a cooperating aperture on a fence post; Mounting a spacer on a coupling projection on the slat;

Sliding the slat out of the cooperating aperture to couple with the spacer.

In accordance with one aspect of the present invention there is provided a method of assembly of a fence panel, the method including the steps of: Inserting one or more slat into a cooperating aperture on a fence post;

Inserting a quick release element into the fence post;

Turning the quick release element to hold the slats against the cooperating aperture.

Other aspects are disclosed.

BRI EF DESCRI PTI ON OF THE DRAW I NGS

Preferred embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings in which: Figures 1A and Figure 1B are perspective views of a first fence panel assembly;

Figures 2 and 3 are perspective views of the first fence panel assembly shown partially assembled;

Figures 4A to 4C are detail perspective views of the first fence panel assembly showing a brace member braced between slats;

Figures 5A and 5B are detail perspective views of the first fence panel assembly showing a rail spaced apart from a post;

Figure 6 is front view of a second fence panel assembly;

Figure 7 is a perspective view of component parts of the second fence panel assembly;

Figures 8A to 8C are perspective views of two of the component parts alone and connected together;

Figures 9A to 9F are perspective views of the second fence panel assembly in various stages of assembly;

Figures 10 and 10B are perspective and top views of a locking mechanism for the first or second fence panel assembly;

Figure 11 is an end elevation view of an elongate slat;

Figure 12 is a front elevation view of a fence panel assembly with four slats as shown in Figure 11 in a stacked formation between spaced apart posts;

Figure 13 is a section view (or plan view) of a fence post showing a follower recess for receiving a quick release locking element in the form of a cam;

Figure 14 is a guide cap for fitment into the end of a slat, which facilitates fitting of the slat into a fence post aperture;

Figure 15 are several views of a gate rail extrusion cap;

Figure 16 is an end elevation (or cross section) view of a gate rail extrusion which can receive the gate rail extrusion cap;

Figure 17 is a detail end elevation view of a base edge of Figure 11 ;

Figure 18 is a detail end elevation view of a top edge of Figure 11, which is configured to interengage with the base edge shown in Figure 17;

Figure 19 shows three views of an oval shaped spacer for engagement with elliptical brace members generally shown in Figure 4;

Figure 20 is a quick release locking element shown outlined in Figure 13; Figure 21 are three section views of a slat assembly which shows a central slat section, a slat foot and a slat connector; and

Figure 22 is a connector for a gate rail and a stile.

DETAI LED DESCRI PTI ON OF PREFERRED EMBODI MENTS

Figures 1 A and 1 B show a fence panel assembly 1. The assembly comprises a pair of posts 2 and a plurality of slats 3 secured therebetween. At least some of the slats 3 are braced by a brace member 4 extending from one side, thereby forming a rigid panel. The brace member 4 may be affixed to the slats 3, such as by welding, or in other ways such as by clamping the slats 3 together, and by being selectively adjustable in length, in any one of the ways being to further enhance the rigidity of the panel. Typically a rail 5 is also secured between the posts 2 and engages a top end 6 of each post 2, to brace between posts 2. Figures 2 and 3 show the fence panel assembly 1 during two stages of construction. Figure 2 illustrates an initial stage where some of the slats 3 are engaged with respective apertures 7 extending into the posts 2. Each aperture 7 is dimensioned to receive one of the slats 3. Two brace members 4 are secured to each of the slats 3, and each brace member is disposed at about 25% of the way along the length of the slat, from each end. This typically involves each slat 3 having a brace aperture extending therethrough and dimensioned to receive at least a portion of the brace member 4. When the slats 3 engage the posts 4, the brace apertures align thereby allowing the brace member 4 to be inserted through all of the brace apertures to brace the slats 3.

Optionally, at least some of the slats 3 may be arranged together such that the brace apertures are aligned and the brace member 4 engaged therein prior to securing the slats 3 to either post 2, thereby forming a sub-panel 8. Some sub-panels may be three slats high, others two, others four. This is one advantage of some embodiments of the technology: that some sub panels can be pre-fabricated in jigs and then transported to site and assembled quickly into the stiles on site to form a fence panel. To prefabricate sub-panels, the slats are placed in jigs and then, any one of the following processes is undertaken:

• Held in place in jigs, and then spacers are welded into place; · Held in place in jigs, and then a bracing rod is extended through brace apertures is welded into place

• Some tabs are punched from one long side of the slat, or otherwise formed so as to fit into cooperating brace apertures on adjacent slats when they are fitted into a sub panel. Further optionally, the brace member 4 may be affixed to each slat 3, such as by welding or adhesive, or may be selectively adjustable in length, such as by comprising a threaded section and a nut, thereby allowing the brace to clamp the slats 3 together. Where slats 3 are clamped together, spacers (not shown) may be added between slats 3 to ensure a consistent separation distance therebetween is maintained.

Figure 2 shows some of the slats 3 spaced apart from the posts 2 and connected to each other by two other brace members 4, thereby forming the sub-panel 8. This allows multiple slats 3 to be connected to each other and then inserted into the stile apertures 7, thereby streamlining the assembly process. In order to ease the sub-panel into the stile apertures, a guide cap as shown in Figure 14 is used and fitted into an end of each slat, and the chamfers helps to ease in the slats into the stile apertures 7.

Alternatively, each post 2 may include a channel (shown in Figure 13) dimensioned to receive a slat 3 and into which the slats 3 are slid and retained. In this embodiment, each slat 3 may have a brace aperture extending in one long side thereof, and a brace member (not shown) affixed to and extending from an opposed side. When the slats 3 are slid into the channel, the brace member 4 extending from one slat 3 is aligned with the brace aperture extending into an adjacent slat 3, thereby allowing each brace member to engage a brace aperture in the adjacent slat 3 and brace the slats 3. This arrangement therefore allows the slats 3 to be progressively stacked on top of one another and braced, as the slats 3 are inserted into the channel. Further alternatively, the brace member is not affixed to one side of the slat 3 and instead, is a separate connector (not shown) adapted to engage two adjacent slats 3. In this embodiment, a plurality of connectors can be engaged with slats 3 as they are stacked in the channel, thereby allowing progressive bracing of the slats 3.

Figure 3 illustrates a subsequent stage of construction, where the sub-panel 8 is arranged between the posts 2, prior to the slats 3 being inserted into the apertures 7.

The fence panel assembly 1 may be interconnected with other like panel assemblies (not shown) in order to form a larger fence area. For example, one or more of the posts 2 may be 'double-sided' and define a further plurality of like apertures 7, typically in an opposed side to the first plurality of apertures 7 and aligned therewith, thereby allowing a further plurality of like slats 3 to be connected thereto. In this embodiment, only three posts 2 are therefore required to form two fence panels.

For example, the fence panel assembly 1 may be installed between two brick piers (not shown) spaced apart from one another a distance greater than the length of the slats 3. In this scenario, a first post 2 having a single set of apertures 7 is secured to each pier, and a second post 200 (not shown) having two sets of like apertures 7 arranged in opposed sides of the post 200 is secured halfway between the piers. A first plurality of slats 3 is connected between one side of the second post 200 and one of the first posts 2, and a second plurality of slats 3 is connected between the other side of the second post 200 and the other first post 2. When installed in this way, the fence panel assembly 1 is therefore extended in length to form two panels between the two piers. In this scenario, the rail 5 may be dimensioned to extend between all three posts 2, 200 and brace therebetween. Figures 4A to 4C show two different spacers 9, 10 adapted to engage one brace member 4 with another brace member 4, or the rail 5. Whilst the spacers 9, 10 are shown as separate parts from the brace members 4, it will be appreciated that either spacer 9, 10 may alternatively be an integral portion of the brace member 4.

Figures 4A and 4B show a first spacer 9 being affixed to one end of a first brace member 4. The first spacer 9 defines an aperture 11 dimensioned to receive an end of a second brace member 4. The first spacer 9 is typically used where two sub-panels 8 are constructed and secured between common posts 2, whereby the first spacer 9 connects between aligned brace members 4 in the adjacent sub-panels 8. This ensures a consistent distance is achieved between the adjacent sub-panels 8 and provides a secure mechanical connection between brace members 4, thereby enhancing the rigidity of the fence panel assembly 1. The second spacer 10 is affixed to one end of a brace member 4 and has a protrusion 12 extending therefrom. The rail 5 typically has an aperture extending therein for receiving the protrusion 12. The second spacer 10 is typically used when the rail 5 is secured between the posts 2 above the slats 3 to ensure a consistent distance is achieved between the top-most slat 3 and the rail 5 and to provide a secure mechanical connection therebetween, further enhancing the rigidity of the fence panel assembly 1.

It may be that the cross section of brace member 4 varies. In some embodiments the cross section of brace member 4 may be circular; in other embodiments the cross section of brace member 4 may be non-circular. The reason for the brace member 4 to be non-circular is so as to facilitate assembly. In one embodiment, the non-circular cross-section brace member may be ovoid. When the brace member 4 is non-circular in section, a cooperating spacer may be provided to facilitate assembly. One cooperating spacer 109 is shown in Figure 19. The cooperating spacer 109 is shown to have a base aperture 113 and an upper, rebated aperture 111 so that the second brace member 4 can slide into position into a bight 112 and be then held in position on the adjacent slat 3. Assembly of one panel sub assembly (of, say, four slats) and another panel sub assembly (of, say, three slats), into a pair of end posts, with a rebated spacer 109, would be done by:

1. Sliding the four-slat sub-panel 8 into respective apertures 7 on the post 2;

2. Placing rebated spacers on the top slat of the sub-panel 8, on the brace members 4, so that the rebate openings align to one end of the slat sub-panel;

3. Sliding the three-slat sub-panel 8 along the four-slat sub panel two sub-assemblies so that they enter the respective apertures 7, while keeping the brace members 4 on the base long wall of the three-slat sub-panel 8 above the rebated spacer 109;

4. Lower the three-slat sub-panel 8 down and slide the three-slat sub- panel 8 back along the four-slat sub-panel 8 so that the brace members 4 on the three-slat sub-panel 8 engage the rebate and abut the end of the bight 112. The two sub-panels are now braced by the brace elements 4.

Advantageously, this assembly process is faster and more convenient than known processes.

Figures 5A and 5B show the rail 5 being secured to each post 2. The rail 5 has a post engaging portion 13, 14 arranged at either end thereof. Typically, the post engaging portion comprises one or more protrusions arranged to frictionally engage the post 2.

Figure 6 shows an alternative fence panel assembly 20 comprising a pair of posts 21 having a plurality of slats 22 connected therebetween. A pair of rails 23 are connected to respective ends of the posts 21. The rails 23 are secured to the posts 21 by a plurality of connectors (not visible) to form a rigid frame. The assembly 20 may therefore be used as a free-standing structure, such as for a gate. Figure 7 shows the fence panel assembly 20 disassembled in kit form. In addition to the components described above, the assembly 20 further comprises four post connectors 24 and four rail connectors 25. Each post 21 is at least partially hollow and includes a plurality of apertures 26 dimensioned to receive the ends of one of the slats 22.

Figure 8A shows one of the rail connectors 25 in isolation. The rail connector 25 has a rail engaging portion 27 typically dimensioned to frictionally engage a hollow portion of one of the rails 23. The rail connector 25 also comprises a post engaging portion 28 dimensioned to be received by one of the apertures 26. The post engaging portion 28 further comprises an aperture 29 dimensioned to receive a portion of the post connector 24. Whilst the rail connector 25 is shown as separable from the rail 23 it will be appreciated that the rail connector 25 may be an integral part of the rail 23.

Figure 8B shows one of the post connectors 24 in isolation. The post connector 24 has a head 30 shaped to fit within the post 21 and a shaft 31 extending therefrom. The shaft 31 is arranged to engage the aperture 29 in the rail connector 25 to secure an associated rail 23 to a post 21. This relationship is illustrated in Figure 8C. The post connector 24 further comprises one or more projections 32 extending from the head 30, the protrusions 32 arranged to guide the connector 24 within the post 21 and therefore assist alignment of the shaft 31 with the aperture 29.

Figures 9A to 9F show various stages of constructing the fence panel assembly 20.

In Figure 9A, one of the rail connectors 25 is shown being inserted into an end of one of the rails 23.

In Figure 9B, the rail connector 25 is engaged with one of the apertures 26 in one of the posts 21 and one of the post connectors 24 is positioned for insertion into the post 21. The shaft 31 is slightly offset from the aperture 29 so as to increase friction. In Figure 9C, the post connector 24 is shown being inserted into the post 21.

In Figure 9D, the post connector is shown inserted in the post 21. The head 30 of the connector 24 is shown spaced apart from an end of the post 21, thereby allowing a cap (not shown) to also be secured to the post 21, or a bearing hinge (not shown) to be secured therein.

In Figure 9E, two rails 23 are engaged with one post 21.

In Figure 9F, the slats 22 are inserted into the apertures 26 in one post 21 and positioned for insertion into the apertures 26 in the other post 21. Once the slats 22 and the exposed rail connectors 25 are inserted into the apertures 26, the post connectors 24 are inserted into either end of the post 21 and engage the respective rail connectors 25, thereby completing the construction of the fence panel assembly 20.

A fence panel may be assembled this way, or a gate panel may be assembled in a very similar way. Some gates require a stiffer gate rail extrusion which is shown in Figures 15 and 16 and described in detail hereinbelow. The gate rail extrusion includes keys and cooperating keyways in the gate rail connector to increase stiffness as shown and described. In the embodiments shown, the gate can be assembled without welding on site, which is advantageous and easy, and the dimensions of the gate can be slightly varied because of the play in the gate stiles, so that the gate (and the fence panel, for that matter) can be flexible in dimension and the installer has some flexibility to overcome topographical and other site issues. Figures 10A and 10B show a quick-release fastening or locking mechanism 40 adapted to be used with either fence panel assembly 1, 20 described above. The quick release locking mechanism 40 comprises a locking bar 41 having at least a portion defining a cam-shaped or elliptical cross section. The locking bar 41 is inserted into one of the posts 2, 21 and arranged in a void between an inner surface of the post 2, 21 and the slats 3, 22 extending therein. The locking bar 41 is then rotated within the void until the cam-shaped portion urges against at least some of the slats 3, 22 and the post 2, 21. This therefore firmly engages the slats 3, 22 with the post 2, 21 and eliminates undesirable noise caused by movement thereof, for example, due to wind.

To assist with the rotation of the locking bar 41, a handle 42 adapted to engage the bar 41 may be provided. Engaging the handle 41 in an end of the bar 41 and manually rotating the handle 42 thereby allows sufficient torque to be exerted to urge the bar 41 between the slats 3, 22 and the post 2, 21. For example, the end of the bar 41 may define a hexagonal socket (not shown) and the handle 42 define a complementary hexagonal portion dimensioned to fit within the socket, thereby allowing the handle 42 to engage the bar 41 and facilitate rotation thereof. To further assist with this rotation, a base (not shown) may be provided at an end of the post 3, 22 having a receiving portion to receive a portion of the bar 41 and guide its rotation. For example, the bar 41 may have a shaft (not shown) extending from an end which is received in a complementary aperture in the base, in order to correctly position the bar 41 relative to the slats 3, 22 and facilitate rotation thereof. Figures 11 to 14 show another embodiment of the present invention. During discussion of this new embodiment, numerals like those used during discussion of other embodiments will be used, to describe like features.

Generally shown at 101 there is shown a fence panel assembly.

Shown at 103 is an elongate slat which includes opposed long sides 150, 151 extending between opposed first and second ends 152, 153, and one or more coupling or bracing elements 104 disposed along at least one of the opposed long sides 150, 151 for coupling or bracing with other elongate slats.

The opposed long sides 150, 151 are disposed along the sides of slat faces 154, 155. The coupling elements shown in Figures 11 and 12 are coupling formations 104 disposed into each of the opposed long sides 150, 151, such that a first coupling formation 164 on one side is formed to cooperate with a second coupling formation 165 on the other long side, such that when the elongate slats 103 are stacked one atop the other such as shown in Figure 12, the one or more cooperating coupling formations 164, 165 on the long sides couple with one another for support or bracing of the slats along the long side.

The first and second coupling elements 164, 165 each include a coupling recess open at an outer end. One recess may be slightly narrower than the other so that one coupling element may fit at least partially within the recess of the other.

The first and second coupling recesses 164, 165, include one brace arm 166, 167 so as to define one wall of the recess.

Another embodiment of coupling element for a single-walled slat is shown in Figures 17 and 18. The brace arm 264 of one coupling element may have a notches or rebates or tabs or ridges on their end shown clearly in Figs 17 and 18 so as to fit with a recess in the other coupling element 265 to couple therewith.

The coupling elements 104 are configured to receive a reinforcing element (not shown) in the recess for strengthening the slats against forces normal to the slat. The reinforcing element could be a bar or cylinder or batten of about the same cross-section as the recess, to couple and strengthen the recesses together. This arrangement works generally because the slats are inhibited from vertically separating when installed by being retained with a rail on the top of the panel, or just by being locked against the side of the fence post 102, which provides a certain vertical retention force for the slat ends.

The coupling elements 164, 165 in some embodiments are identical and abut so as to provide a substantially seamless join. In the embodiment shown in Figures 11 and 12, the profile shape is two sinusoidal pitches and the slats join at the same portion on the sinusoidal waveform so that the join seems to be seamless.

Coupling elements 264 and 265 shown in Figures 17 and 18 are shown, one (265 on the bottom edge) as a hollow cylinder with a groove along an outside wall to interengage and lock with the above mentioned tab or ridge 264 disposed on distal ends of arms 266, 267.

The elongate slats 103 have decorative or acoustic attenuation elements, in the form of profiles 170 on the faces. The profile 170 on the elongate face is sinusoidal. The decorative or acoustic attenuation elements are cuts 175 disposed along the length and shown extending the pattern across four slats, in a quartich form.

The elongate slat 103 is extruded from aluminium or plastic.

The elongate slat 103 can be of any particular construction - rolled, or extruded or a combination of the two, or some other injection or other moulding process. In embodiments shown in Figure 21, the elongate slat 103 is a combination of a rolled centre section 167 fashioned out of 1.6mm steel and upper and lower bracing sections 204 and 304. The lower bracing section 204 includes a coupler 209 for coupling two slats together the coupler 209 including two slat receivers 211 and 212 for receiving slats. The upper bracing section 304 is a termination brace for providing an upper or lower terminating slat with a foot for abutting an upper or a lower rail 5. The terminating brace provides more strength than would otherwise be present with a rolled wave steel section.

There is shown in Figure 13 a fence post 102 for receiving the slats 103. The fence post includes at least one slat-receiving opening 107 on one face for receiving at least an end portion 151, 152 of an elongate slat 103 therein. A quick-release fastener 141 is disposed substantially within the post 102 and is configured to turn about an actuation axis 180 (parallel with the post 102) so as in use to hold an elongate slat 103 against a portion of the slat-receiving opening. The quick release fastener shown in detail on Figure 20 has a hexagonal bore so as to receive an Allen key to move it along the following surface between the unlocked and locked positions.

There is shown in Figure 13 a single slat-receiving opening which extends along the post 102 from a top to a bottom. The post 102 in this

embodiment is in the form of a channel, extruded, folded, or rolled.

The quick release fastener 141 holds the slat 103 against the aperture or channel opening 107 by friction. There is no piercing of the slat 103.

The fastener 141 is a fastener element which is cam-shaped or generally non-circular in cross-section so that it needs only to be turned about an actuation axis less than one full rotation to move between a free position and a fastened position. The cam shown at 141 is an ovoid shape which only need be turned less than about 90° to move between the unlocked position, and the locked position (shown in Figure 13).

The post shown at 102 in Figure 13 shows a following recess 185 for guiding the fastener element 141 between the unlocked and the locked positions. The following recess 185 includes an elongate aperture generally shaped as an inverse to that of the ovoid cam.

Figure 14 shows a guide cap shown at 190 which fits into a slat which has a rectangular hollow section. It helps to guide the end of the slat 3 into an aperture 7.

Figures 15 and 16 show a section view of a gate rail 105 and a gate rail connector 125 which are cooperating sections. The internal section of gate rail 105 is complex, and includes keyways 195 and keys 196 so as to increase strength of interengagement. Figure 19 shows a spacer 109 with slots formed therein. An advantage of these spacers 109 is that the first sub-panel 8 can be fully inserted in to posts 2 on both ends of the sub panel 8. Then, the spacers 109 can then be placed on an oval rod/brace 4 which oval brace cooperates with the oval slot in the spacer. Thus, the spacer 109 is configured to be disposed over the brace 4 with its cooperating central slot positioned to receive the adjacent sub panel 8 sliding in from one end. In use the oval brace 4 prevents the spacers turning, as they might on a simple round brace, thus keeping the slot located in the most useful position for supporting the sub panels 108.

Figure 22 shows a gate stile connector pin 124 which can be put in place to connect the gate rail and stile. There are two ovoid cutouts so that the installer can then insert the quick release element 41 and with a hex-head tool, then engage the quick release and hold the slats in place in the stile or post.

Advantageously, embodiments of the present invention facilitates

construction of fences and gates with a minimum of skill and tools.

I N DUSTRI AL APPLI CABI LI TY The invention can be utilised in building construction, farming and gardening.