This invention relates to a physical barrier or fence.
One type of barrier makes use of a high density steel mesh. Typically, mesh panels are prefabricated under factory conditions and each panel is secured between and to an adjacent pair of posts which have lower ends embedded in the ground. Each panel is normally stiffened to prevent undue flexure of the panel by forming the panel with at least one horizontally extending reinforcing channel which, in cross section, is U-shaped or V-shaped. The channel is defined by bending appropriate portions of rods which make up the mesh.
The security rating which is provided by a fence may initially be adequate but, in many instances, due to a variety of factors, a higher security rating may be required of a fence after it has been erected. It is desirable for cost and other reasons to be able to upgrade a fence to achieve an acceptable degree of security, as opposed to erecting, from scratch, a separate fence. It is also desirable to be able to erect a fence which, ab initio, has a high security rating.
An object of the present invention is to address, to at least some extent, the aforementioned factors.
The invention provides a barrier which includes a plurality of elongate vertically extending supports which are respectively spaced apart from one another along a barrier line, a plurality of first mesh panels, wherein a respective first mesh panel is secured to and extends between a first support and an adjacent second support of the plurality of supports, the first mesh panel including first and second vertically extending edges fixed respectively to the first and second supports and upper and lower horizontally extending edges, and in respect of each said first mesh panel, a respective deterrent structure which is fabricated separately from the first mesh panel, which opposes at least a part of the first mesh panel and which is secured to at least one of the first mesh panel, and the first and second supports.
The deterrent structure is used to enhance the capability of the barrier, between the first and second supports, to resist attack.
The first mesh panel may include a plurality of horizontally extending reinforcing formations, which are vertically spaced apart from one another, wherein each formation, in cross-section, generally has a V- or U-shape.
The deterrent structure may take on any appropriate form determined primarily by the degree of additional attack resistance which is required for the barrier. Thus the deterrent structure may, in one form of the invention, include at least a second mesh panel which is positioned between two of the aforementioned horizontally extending reinforcing formations. In one form of the invention these reinforcing formations are adjacent each other. Each of a plurality of the second mesh panels may be positioned between a respective adjacent pair of the horizontally extending reinforcing formations.
In a different form of the invention a second mesh panel is secured in position adjacent the first mesh panel between first and second said horizontally extending reinforcing formations in the first mesh panel and the second mesh panel overlies at least one said horizontally extending reinforcing formation in the first mesh panel.
In another form of the invention the deterrent structure comprises a plurality of spaced lengths of flat bar secured in position adjacent the first mesh panel between a first said horizontally extending reinforcing formation in the first mesh panel and a second said horizontally extending reinforcing formation in the first mesh panel. The said plurality of lengths of flat bar may extend vertically, or horizontally, or vertically and horizontally.
In a variation of the invention the deterrent structure comprises a framework made from a plurality of opposing tubular members, e.g. of square or rectangular cross-section positioned adjacent the first mesh panel and extending between two of said horizontally extending reinforcing formations in the first mesh panel.
The first mesh panel may include a first array of elongate members which are positioned spaced apart from one another and which extend generally horizontally, and a second array of vertically extending members which are spaced apart from one another and which extend generally vertically and wherein the first array is positioned so that it overlies the second array and the elongate members of the first array are welded to the elongate members of the second array at respective points of contact.
The horizontally extending members may have a first spacing between adjacent pairs of the members and the vertically extending members may have a second spacing between adjacent pairs of the members which is greater than the first spacing.
The horizontally extending members may be of any suitable form and for example are made from round bar, wire or rod of a circular cross section or the like. In one form of the invention the vertically extending members include or comprise a plurality of flat bar elements. A significant benefit associated with the use of the flat bar elements lies in the fact that a flat bar is difficult to cut with a bolt cutter or a similar instrument.
In one form of the invention the deterrent structure includes a plurality of tubular members which are respectively filled with an attack-resistant material such as a cementitious or ceramic material, an ultra-hard settable material or the like.
If the deterrent structure presents at least one upwardly facing surface adjacent the first mesh panel that surface should be inclined so that it does not readily provide a foothold or a handhold for an intruder who is attempting to scale the barrier.
To enhance the strength of the barrier a third support of the plurality of supports may be located adjacent the first support and a fourth support of the plurality of supports may be located adjacent the second support.
Each support of said plurality of supports may include at least one vertically extending member which may be tubular. To increase the strength of the barrier each of the supports may comprise at least two of the vertically extending tubular members which, optionally, are substantially identical to each other in cross-section. The vertically extending members may be secured to each other in any appropriate way, eg. by means of welding or through the use of suitable fasteners.
In one form of the invention each support comprises a respective tubular member which is braced by means of a stay or a web to enhance its strength and load-bearing capability.
Each support may comprise a respective tubular member which is filled with concrete or any other suitable settable material and, optionally, at least one longitudinally extending reinforcing member is embedded in the concrete or settable material.
The invention is further described by way of examples with reference to the accompanying drawings in which:
A first mesh panel 22 is positioned between and secured to a pair of the adjacent supports 12 and 12A. The first mesh panel 22 has a horizontal upper edge 30, an opposed horizontal lower edge 32, a first vertical edge 34 with a flange 34A, and a second vertical edge 36 with a flange 36A (not shown). The flanges 34A and 36A are attached to the supports 12 and 12A respectively using suitable security fasteners.
A similar arrangement is adopted between each pair of adjacent supports 12.
The first mesh panel 22 (see
A deterrent structure 42 is attached to the first mesh panel 22. The deterrent structure 42, in this example, includes three substantially identical mesh panels 44A, 44B and 44C respectively which are shaped to fit between adjacent reinforcing formations 40A and 40B, 40B and 40C, and 40C and 40D, respectively, as is shown in
The respective flange 50 of each second panel 44A to 44C overlies at least a part of a surface 58 of the support 12. The panel (44A to 44C) is secured to the support 12 using bearing plates 52A and fasteners 56A generally in the manner which has been described in respect of the first mesh panel 22.
The attachment arrangement shown in
A deterrent structure 82, which is used in place of the deterrent structure 42, includes a plurality of panels 84A, 84B and 84C which are similar to the panels 44A to 44C. However, the panels 84A to 84C have flanges 90 which are bent through 90° relative to what is shown in
The deterrent structure 100 comprises a large panel 102 with upper and lower sloping horizontally extending flanges 104 and 106 respectively. The panel 102 overlies intermediate horizontally extending reinforcing formations 40B and 40C respectively in the first mesh panel 22. Edges 104A and 106A of the flanges 104, 106 are respectively in abutment with the junctions of the reinforcing formation 40A and an adjacent vertically extending mesh panel section 108 and a junction of a vertically extending mesh panel section 110 and the horizontally extending reinforcing formation 40D, of the first mesh panel 22. This is done for the reasons which have been alluded to.
The panel 102 has opposed planar flanges 114 at its vertical edges (only one flange is shown in
In the preceding examples the deterrent structures are based on the use of additional sections formed from a mesh material which is the same as the mesh material embodied in the first mesh panel 22.
The deterrent structure 140 includes three components 140A, 140B and 140C which are substantially identical to each other. Each deterrent component includes horizontally extending tubular elements 142 and 144 respectively and vertically extending tubular elements 146 which are spaced apart from one another in a horizontal sense. Opposing ends of the elements 146 are welded to respective surfaces of the elements 142 and 144. The elements 146, at opposed vertical edges of the structure 140, are fixed via a respective bearing plate 148 and fasteners 150 to a side 152 of a tubular member 14. The bearing plates 148 overlie flanges 34 of the first mesh panel 22.
Flat bar strips 156 and 158 respectively, inclined to the vertical, are welded in position to the horizontally extending tubular elements 142 and 144 respectively to ensure that no surfaces, which provide a foothold or handhold to an intruder attempting to scale the barrier, are presented by the deterrent structure.
Various techniques have been described for upgrading the barrier. In order to strengthen each tubular member 14 an additional tubular member 14A can be used. Another technique is shown in
In the various deterrent structures it is important that all horizontal elements which face upwardly, typically at boundary positions, are orientated or otherwise have flat bar sections attached to them so that sloping surfaces are presented which do not constitute footholds or handholds to an intruder.
The tubular elements shown in
The upgrading of the barrier may thus be accomplished by the addition to an existing mesh panel or the provision, in conjunction with a mesh panel, of one or more high density welded mesh sections, flat bars or tubular deterrent structures. A composite panel may be fabricated to have ballistic resistant properties.
Smaller panels of the kind shown in
An advantage of upgrading an existing barrier is that the bulk of the cost (of upgrading) is only incurred if circumstances change. Use is made of existing posts and foundations, and upgrading is quick and relatively easy to carry out. A user may select a specific area to be upgraded, ie. an area where the risk of intrusion is great. It is then not necessary to upgrade the entire barrier or fence. Care should be taken to avoid creating a foothold or handhold when installing the deterrent structure. In each instance an upper edge of a mesh panel or framework (whether of flat bar or tubes or the like) should present a sloping surface of at least about 45° to the vertical and must fit flush with a surface of an existing mesh panel so that no meaningful foothold or handhold is formed.
Number | Date | Country | Kind |
---|---|---|---|
201602486 | Apr 2016 | ZA | national |
Number | Name | Date | Kind |
---|---|---|---|
4553740 | Bailey | Nov 1985 | A |
4673166 | MacDougall | Jun 1987 | A |
5542649 | Allegaert | Aug 1996 | A |
5556080 | Vise | Sep 1996 | A |
6113076 | Hancock-Bogese | Sep 2000 | A |
6199831 | Patrick | Mar 2001 | B1 |
6206347 | Kelley | Mar 2001 | B1 |
6581914 | Saura Sotillos | Jun 2003 | B2 |
7118096 | Petrozziello | Oct 2006 | B2 |
D605781 | Cochrane | Dec 2009 | S |
9428934 | Payne | Aug 2016 | B1 |
20040004210 | Bauer | Jan 2004 | A1 |
20070170411 | Ribak | Jul 2007 | A1 |
20150292170 | Cochrane | Oct 2015 | A1 |
20180058094 | Filiba | Mar 2018 | A1 |
Number | Date | Country | |
---|---|---|---|
20180283042 A1 | Oct 2018 | US |