The present invention relates to a protective shelter and, in particular, to such a shelter that can provide protection within a war zone and which can be readily assembled in a quick, secure and reliable manner.
While a variety of requirements arise for temporary, or at least quickly-built shelters, there is generally a compromise between the level of protection offered by the shelter and the speed, reliability and ease with which such a structure can be built.
Also, the degree of protection required by the shelter can change over time and known protective shelters, while perhaps providing an appropriate initial level of protection, may not be suited to a scenario in which a lesser, or greater, degree of protection is required.
The invention seeks to provide for a protective shelter having advantages over known such shelters.
A protective shelter is disclosed. In one aspect, the protective shelter comprises opposite outer supports and a roof structure extending between the opposite outer supports. The roof structure comprises a plurality of tray members arranged to receive earth, sand or aggregate material defining an inner skin to provide a first level of protection in the roof structure. The tray members are supported by beams.
In one embodiment, the beams are arranged to define a shallow arch across the shelter such that the internal height of the shelter centrally, and away from the opposite outer supports, is greater than the height of the opposite outer supports.
In a preferred embodiment, the beams are transverse beams extending between the opposite outer supports.
In another embodiment, the roof structure further comprises a screen that is spaced above and extending over the tray members to provide a second level of protection in the roof structure.
In another embodiment, the roof structure further comprises roof trusses arranged to support the screen.
In another embodiment, the opposite outer supports are walls or gabions.
In a preferred embodiment, the gabion is a cage structure adapted to be filled with a filling material in order to provide a structural block. In an embodiment, said cage structure comprises a wall or walls at least partially defined by open work mesh, and a lining material lying to the inside of said open work mesh to enable the cage to be filled with a particulate material which would pass through the open work mesh were it not for the presence of the lining material.
In another aspect, the protective shelter comprises opposite outer supports; and a roof structure extending between said opposite outer supports; wherein said roof structure comprises a plurality of tray members arranged to receive earth, sand or aggregate material defining an inner skin to provide a first level of protection in said roof structure, wherein said tray members are supported by beams, wherein said beams are arranged to define a shallow arch across the shelter such that the internal height of the shelter centrally, and away from said opposite outer supports, is greater than the height of said opposite outer supports.
In another aspect, the protective shelter comprises opposite outer supports, a roof structure extending between the opposite outer supports, and a stand-off wall located outside a door of the shelter. The roof structure comprises a plurality of tray members arranged to receive earth, sand or aggregate material defining an inner skin to provide a first level of protection in the roof structure and a protective screen, spaced above and extending over the tray members, to provide a second level of protection in the roof structure.
In one embodiment, the protective shelter further comprises a porch extending from the roof structure to the stand-off wall.
The invention is described further hereinafter, by way of example only, with reference to the accompanying drawings in which:
a is a side elevational view showing additional detail of the connecting structure roof trusses and supports of the protective shelter of
b is a side elevational view showing yet additional detail of the roof trusses and supports of the protective shelter of
a and 6b illustrate connecting members for connecting roof trusses within the roof structure to transverse beams of the roof structure.
b is a side elevational view showing yet further additional detail of the roof trusses and supports of the protective shelter of
As will be appreciated from the following description, examples of a shelter embodying the present invention can be quickly and, importantly, reliably constructed in a manner requiring a minimum number of personnel and, critically, in a manner such that each separate component of the structure can be removed and lifted single-handedly.
Also, all separate components can advantageously be of a size such that they are readily transportable, in flat-packed unassembled form on a pallet, such as a pallet of dimensions 2 meters×2.2 meters.
As will be appreciated, the invention provides for a protective shelter offering opposite outer supports and a roof structure extending between the supports, wherein the roof structure comprises a plurality of tray members arranged to receive earth, sand or aggregate material defining an inner skin to provide a first level of protection in the roof structure, and the tray members are arranged to be supported by beams, wherein the beams are arranged to define a shallow arch across the shelter such that the internal height of the shelter centrally, and away from the opposite supports, is greater than the height of said supports.
In order to assist the quick and reliable formation of such a shallow arch structure, the supporting beam members advantageously comprise beams of identical shape and configuration and the end faces of which are angled, or bevelled, in respect to a plane perpendicular to the longitudinal extent of each of the beams. The angle to the said plane is advantageously 7.5°.
As a further advantage, the ends of the transverse beams that are arranged to be supported by the side walls are arranged to be received by anchor assemblies. Preferably, a vertical member of the transverse beams includes sections to accommodate flitch plates, for supportively connecting the beams. Preferably still, the sections are controlled tolerance channels in the beams. Advantageously, securing the transverse beams with the flitch plates in this manner creates a strong continuous roof beam.
The anchor assemblies advantageously serve to space the transverse beams along the length of the shelter and are arranged such that each transverse beam is effectively connected to, in a secure manner, and sandwiched between, adjacent anchor assembly units. Alternatively, it can be considered that each anchor assembly unit is effectively securely connected to, and sandwiched between, adjacent transverse beams.
In any case, the anchor assembly units, through their secure engagement to the transverse roof beams, provide for a rigid footing/support structure that extends along the length of the upper surface of the walls of the shelter and thereby combine to effectively define a lintel beam extending along the length of the wall. Such rigid supporting structure provided by the interconnected anchor assembly units serves to define the aforementioned lintel beam in a manner such that, should the outer wall suffer damage, or the integrity thereof be in any way compromised, the rigidity and stability of the overall roof structure can remain intact advantageously serving to retain the roof structure in place in spite of any such damage to the wall(s).
The structure of the invention can advantageously include a second laterally extending layer, spaced from the tray members and arranged so as to define a pre-detonation screen.
The pre-detonation screen is advantageously spaced from the initial layer formed by the tray members and the soil, sand, aggregate layer by a distance in the order of 1 meter.
Preferably, the tray members comprise a series of interconnected identical tray members having mutually connectable engagement formations at opposite ends thereof.
As a further feature, the portions of the roof structure provided above the earth, sand or aggregate layer can advantageously be formed from the interconnected metal poles, for example, such as scaffold poles.
Such poles are arranged to provide roof trusses and rafter poles, within the overall structure of the roof. As one example, the pre-detonation screen can comprise plywood panels having a thickness of 19 mm.
As should be appreciated from the above, and from the description below, the invention is particularly advantageous insofar as the roof structure can be readily formed on gabion units which are arranged to form the opposite walls of the shelter.
The wall structures can be formed from structural blocks such as those that are the subject matter of European Patent 0466726.
The overall protective shelter can then be quickly and reliably constructed as required, and in a manner responsive to the level of danger faced, and the level of protection required.
For example, once the gabions are in place to form the walls of the shelter, the roof structure can be readily, reliably formed, requiring a minimal number of personnel and, through use of the component parts described herein, in a structurally rigid and reliable manner so as to first provide a basic level of blast protection by way of the transverse beams and interlying series connected trays, as described further herein, and the layer of earth, sand or other aggregate provided thereon.
The level of protection can be further enhanced by inclusion of a pre-detonation screen which, again, can be constructed in a fast, efficient and reliable manner as and when required.
An adaptable degree of protection can then advantageously be provided by a shelter embodying the present invention.
Turning first to
The shelter (10) is provided with opposite side walls (12a), (12b) formed of aligned gabions upon which a roof structure according to the invention is supported.
The roof structure in the illustrated embodiment comprises a pair of parallel longitudinal beams (14), (16) extending along the length of the shelter (10) and parallel to the opposite walls (12a), (12b).
Supported upon the longitudinal beams (14), (16) and extending in a manner perpendicular thereto across the width of the shelter (10) so as to be supported in part upon the upper surface of the opposite walls (12a), (12b) is a transverse beam structure comprising three elongate series connected transverse beams (18), (20), (22).
Each of the transverse beams (18), (22) that is supported on the upper surface of each of the opposite walls (12a), (12b) is arranged to engage with a roof beam anchor assembly unit (23). In addition to providing secure support for the transverse roof beam structure (18), (20), (22) on the opposite walls (12a), (12b), such roof beam anchor assembly units (23) are also arranged to be interconnected by way of their connection to their respective transverse roof beams (18), (22) so as to provide for a rigid and secure lintel beam structure extending along the lengths of the walls (12a), (12b). The shape and configuration and structural detail of each of the roof beam anchor assembly units (23) is illustrated in further detail later with reference to
As can be seen from
As will be appreciated from the further discussion of
The provision of such a shallow arch advantageously provides for a suitable internal height to the protective shelter, whilst advantageously limiting the height to which the supporting opposite walls (12a), (12b) have to be provided, and thus also the thickness to which such walls (12a), (12b) have to be provided.
Through such careful design of the structural components of the roof as illustrated in
Extending upwardly from the transverse beam structure (18), (20), (22), and from locations approximate the ends of the transverse beams (18), (20), (22) are respective pairs of roof trusses (24), (26); (28), (30), (32), (34).
In the illustrated example, the roof trusses are in the form of metal poles and the ends of each respective pair (24), (26); (28), (30); (32), (34) of roof truss poles remote from the transverse beam structure (18), (20), (22) are connected together either directly or by way of further features of the roof structure to be described below.
The respective pairs of roof trusses (24), (26); (28), (30); (32), (34) serve to support rafter poles (36), (38) which extend in a transverse manner across the upper part of the roof structure of the shelter (10) in the manner illustrated.
The outer ends of the rafter poles (36), (38) are connected to eaves poles (40) which extend longitudinally along the roof structure of the shelter (10) and in a direction parallel to the opposite walls (12a), (12b).
The inner ends of the rafter poles (36), (38) are connected to a central ridge pole (42) which, in the illustrated example, can comprise a scaffold tube, and which serves to define the upper extent of the roof structure of the shelter (10).
As with the eaves poles (40), the ridge pole (42) extends longitudinally along the length of the shelter (10) and in a manner parallel to the opposite outer walls (12a), (12b) and the longitudinal beams (14), (16).
As a further feature, adjustable internal props (44), (46) are included so as to provide internal support to the longitudinal beams (14), (16).
Although the illustrated embodiment is designed around an outer wall of gabions, if insufficient support might be provided thereby, adjustable props (48), (50) can likewise be provided within the wall structure so to provide appropriate support to the roof structure as illustrated.
As will be described in further detail below, the rafter poles (36), (38) and the outermost roof trusses (24), (34) serve to provide support for a pre-detonation screen (52) which, in the illustrated embodiment, can be formed of plywood panels.
To complete the structure, and provide some weatherproofing thereto, an outer roof fabric cover (54) is included which can be anchored to the outer surfaces of the opposite walls (12a), (12b).
As will be appreciated from
Insofar as the pre-detonation screen provided by the plywood panels (52) is of an appropriate thickness to achieve detonation of, for example, incoming mortar rounds, the product of any such blast is then advantageously absorbed by the earth, sand or aggregate layer (18) located on the trays of the roof structure so as to maintain overall integrity of the inner layer of the roof structure and provide an appropriate level of protection for personnel located within the structure.
Advantageously, the distance between the pre-detonation screen (52) and the earth, sand or aggregate layer (80) is in the order of 1 meter so as to provide for appropriate blast resistance.
Turning now to
As will be appreciated, while only one of the transverse beam structures (18), (20), (22) was illustrated in the sectional view of
Although not visible in
The exact configuration of one example of such a tray is discussed further below in relation to
Insofar as the series of interconnected trays located between each pair of transverse beams (18), (20), (22) is arranged to received a layer of soil, sand or other aggregate, it has been found advantageous to include a geotextile layer upon the trays and prior to the provision of the layer of soil, sand or aggregate. The geotextile material is advantageously clipped, or generally secured in any appropriate manner, to the transverse beams.
Such a geotextile layer (not shown in the drawings) serves to prevent the ingress of sand through the roof structure and into the accommodation offered by the protective shelter, and further serves to enhance the integrity of the soil, sand or aggregate layer should damage be suffered by any one or more of the supporting trays.
Turning now to
Again, and as with the transverse beam structure (18), (20) and (22) illustrated further in
With regard to
The pre-detonation screen (52) provided by the plywood sheets is illustrated for completeness in
Turning now to
The embodiment is illustrated through reference to a roof truss (26) such as that illustrated in
With regard to
a is a transverse sectional view of the beam (18) of
The inverted T section of the roof beam (18) is clearly illustrated in
As will be appreciated, each end face of the transverse beam (18) is of an angled or bevelled configuration and preferably offers an angle of 7.5° to a plane perpendicular to the longitudinal extent of each transverse beam.
Referring again to
Thus, a secure structure can be formed in an efficient and speedy manner since positional selection of each of the transverse beams (18), (20), (26) is not required.
Also illustrated within
Turning to
As will be appreciated, each of the transverse beams (18), (20), (22) has itself an inverted T cross section such that each pair of adjacent beams offers a ledge between which the elongate trays can be mounted.
As with the transverse beams (18), (20), (22) that extend in series across the width of the shelter (10), the trays (62) are arranged to be connected in a series manner extending across the width of the shelter (10), and of course in between the respective parallel transverse beam structures (18), (20), (22) and the respective ends of which are provided with co-operating engagement formations (64), (66).
As will be appreciated from
Again, such features are particularly advantageous in allowing for a quick, yet secure, formation of a strong but lightweight roof structure for the shelter. The structure of each of the trays can be further enhanced by the inclusion of laterally extending roofs (68) so as to provide bend-resistance to any blast that might occur in the vicinity of the pre-detonation screen, and also to assist in stabilising the mass of earth, sand or aggregate provided thereon.
Turning now to
Welded in a vertical orientation at each end of the roof beam anchor assembly unit (23) is a pair of end plates of which one (25) is illustrated in
Each end plate (25) includes a pair of aligned apertures (27) arranged for the engagement of the roof beam anchor assembly unit (23) with, for example, the transverse beam (18) as illustrated in
Turning to
Here the vertically extending side wall portions (25) and (25′) are clearly shown along with the laterally extending plate (31). The location of each of the respective footing plates (29), (29′) is also illustrated.
In use in the arrangement of
As illustrated in
Then, above the crate-supported gabion units offering the protective porch (76) for such roof structure to the doorway for the protective shelter, an extension of the pre-detonation layer can be provided so as to extend the level of protection offered by the roof structure to the general internal region of the protective shelter, to the region of the shelter's doorway.
It should of course be appreciated that the pre-detonation layer can be formed with any appropriate material, as indeed can the structure for supporting the earth, sand or aggregate layer. However, the alloy envisaged for the illustrated embodiment of the present invention proves particularly advantageous in view of its weight/strength ratio. It will further be appreciated that the features of the protective shelter as described herein can be supplied in unassembled flat-pack form for later assembly.
All publications and patent applications in this specification are herein incorporated by reference as if each individual publication or patent application were specifically and individually indicated to be incorporated by reference in entirety. Although the foregoing invention has been described in some detail by way of illustration and example for purposes of clarity of understanding, it will be readily apparent to those of ordinary skill in the art in light of the teachings of this invention that certain changes and modifications may be made thereto departing from the spirit or scope of the invention described herein.
Number | Date | Country | Kind |
---|---|---|---|
0709319.8 | May 2007 | GB | national |
0709569.8 | May 2007 | GB | national |
0800652.0 | Jan 2008 | GB | national |
0803661.8 | Feb 2008 | GB | national |
Number | Name | Date | Kind |
---|---|---|---|
948824 | Patterson | Feb 1910 | A |
1821355 | Murray | Sep 1931 | A |
2793720 | Hawes | May 1957 | A |
2985264 | Leonard, Jr. | May 1961 | A |
3008435 | Dupuy | Nov 1961 | A |
3206896 | Hayes | Sep 1965 | A |
3820294 | Parker | Jun 1974 | A |
3940892 | Lindbergh | Mar 1976 | A |
4283888 | Cros | Aug 1981 | A |
4590721 | Berg et al. | May 1986 | A |
4592184 | Person et al. | Jun 1986 | A |
5159790 | Harding | Nov 1992 | A |
5740643 | Huntley | Apr 1998 | A |
6076319 | Hendershot et al. | Jun 2000 | A |
7073306 | Hagaman | Jul 2006 | B1 |
7353642 | Henriquez | Apr 2008 | B1 |
Number | Date | Country |
---|---|---|
0 466 726 | Nov 1995 | EP |
8602688 | May 1986 | WO |
Number | Date | Country | |
---|---|---|---|
20080283106 A1 | Nov 2008 | US |