DE69507642T2 - DEVICE AND METHOD FOR PRODUCING A VEGETABLE CLADDING OF AN EMBARK - Google Patents

Abstract

The present invention provides for a method and apparatus for supporting vegetative growth on a slope face in which a first layer member (12) can be provided for extending over at least part of the slope, a second layer member (14) can be provided for extending in front of said first layer member (12) and arranged to be spaced therefrom and to define a region (26) therebetween for receiving growing medium and wherein connection means (16) are providing for connecting said first (12) and second (14) layer members together in a manner which allows for the support of the growing medium, and any vegetative growth associated therewith, without prejudicing the mechanical stability and strength of the apparatus.

Description

The present invention relates to a method and a device for producing a greenable covering of an embankment.

The need to provide a formation having a steep slope arises in a large number of examples at present on building sites and construction sites, and particularly those associated with transport routes, for example railway lines and motorways. In particular, it is often necessary to provide an embankment or cutting to enable the construction of the transport link such as a motorway in the required direction, or the widening of the motorway.

In order to reduce the cost of such construction projects - which cost arise particularly from the amount of land required for the project - it is often necessary to provide embankments or cuttings with relatively steep slopes. Quite often such steep slopes have to be constructed taking into account a geology which does not provide a naturally supported slope with such steep angles and therefore it has become necessary to provide structural support for such steep slopes.

Given aesthetic considerations, it has also become common practice to provide steep slopes with some form of vegetative cover, such as grass cover, to reduce the environmental impact of the development. Furthermore, in some examples, it has become necessary to provide some form of suitable vegetative cover, such as grass cover, for pre-existing slopes which, given their nature, may not readily support such vegetative cover. Recently, a variety of materials, such as geosynthetics, have been used in the construction of reinforced earth embankments with so-called "soft surfaces". However, even recently devised devices and methods for the construction of such embankments are particularly disadvantageous in that they have a disadvantageously limited ability to establish and maintain a vegetative cover and therefore, within a relatively short time, the embankment begins to look worn, bare and generally neglected and unsightly.

Furthermore, conventional embankment support structures are also disadvantageous in that they use materials that degrade when exposed to ultraviolet rays, and this can greatly weaken the supporting characteristics of such conventional structures. In addition, the same materials are particularly sensitive to fire, and are vulnerable to damage if vehicles or vegetation accidentally catch fire.

Furthermore, known support structures prove to be disadvantageously complex and unnecessarily expensive to construct and often require additional devices such as closures to assist in their formation. The size of compaction machinery that can be used with known support structures when forming the slope is also limited. Furthermore, particularly when used adjacent to highways and other roadways, the support structure tends to be severely damaged and dangerously weakened when a vehicle impacts the slope surface.

A method and apparatus for supporting a vegetative facing on a reinforced slope is disclosed in an article, "Grassy slopes pleases planners", Construction Weekly 3 (1991) 17 April No. 15 page 31. A steep embankment is constructed by a succession of layers of compacted earth separated by sheets of geotextile polyester material which are folded in front to retain the earth, and the vegetation is established on the front of the slope by a separate layer of mulch which is pinned in position. During the To construct the embankment, a double layer of geojute is pinned to the reinforced soil surface. The first layer allows for the hand application of a thin layer of topsoil to the surface of the embankment, after which the second layer, which acts as a receiving net for a hydro-seed mulch spray of grass seed and mulch, is pinned on top.

EP-A-0 391 857 (Fehlmann Grundwasserbauten AG) discloses another system for applying a vegetation supporting layer to a slope or wall. In one example, a steep retaining wall consists of reinforced shotcrete anchored in the ground by means of soil nails. The vegetation supporting layer is provided by a three-dimensional grid which is attached to the wall by means of fastening elements, for example nails, screws or pins. The vegetation supporting material is prepared in the form of a mixture consisting of a substrate, a soil compactor and water. The substrate can be humus and/or compost. Preferably, the mixture is sprayed onto the supporting grid.

In another publication PATENT-ABSTRACS OF JAPAN [vol]. 007 No. 025 (M-190), February 2, 1983 JP-A-57 180719 (TOUKOU KENSETSU KK) November 6, 1982, a method is disclosed for lining an existing slope without reinforcing the slope. This discloses a lower wire mesh and an upper wire mesh with a region therebetween containing a growth agent. The connecting elements are formed by a corrugated element between the two and the anchoring mode is by anchors stapled into the slope.

EP-A-0 437 171 (EBERLE LANDSCHAFTSBAU AG) discloses a similar cladding system for a bench which allows for plantable cladding. A first and a metal fabric layer are disclosed which are spaced apart to provide a region between them for the reception of a growth medium. The connecting elements are connected by intermediate anchors, and the Main anchoring elements for securing the device to the slope are provided by means of threaded bolts inserted into the slope. No means are provided for strengthening the slope.

The present invention seeks to provide a method and an apparatus for supporting a plantable covering of a slope which has advantages over such known methods and apparatus.

In accordance with one aspect of the present invention, there is provided an apparatus for supporting a vegetable covering of a reinforced slope, including reinforcing means extending rearwardly into the slope to reinforce the slope, a first layer member extending over at least a portion of the slope, a second layer member extending forwardly of and spaced from said first layer member to provide a region therebetween for receiving a growing medium, and connecting means providing a connection between said first and second layer members when so spaced, characterized in that said first and second layer members and the connecting means are adapted to form a rigid, open-topped box-like structure where the connecting means form the sides thereof, the box-like structure being adapted to form, when in use, said region between the first and second layer members as a channel region extending downwardly to receive the growing medium in the box-like structure to receive growth means introduced through an open end thereof. The device includes means for interlocking the first layer member with the reinforcing means so that when in use the reinforcing means also forms an anchoring means for securing the device to the slope, the first layer member is adapted to retain the slope material when anchored by the reinforcing means.

The invention is therefore advantageous in that a layer of growing medium can be supported between the first and second layer elements without compromising the mechanical strength of the device and which effectively provides a layer of topsoil for the slope intended to support, establish and maintain a plantable cover. Slope dams can therefore be provided which have dedicated soil systems to facilitate the turfing and establishment of vegetation on a flat slope. Also, the invention can of course alternatively provide a dedicated soil system for the establishment of vegetation on relatively steep earthwork cutting surfaces in generally horticulturally inert soil materials, and which incorporates techniques and features to facilitate the stabilization of otherwise potentially unstable cutting surfaces.

A particular advantage of the present invention is that it serves to separate the structural and horticultural requirements from the slope support aspect and allows both to be undertaken and advantageously achieved without mutual disadvantage.

Preferably, said first layer element comprises a substantially planar element which may also comprise a rigid element. For example, said first layer element could advantageously comprise a rigid mesh element and in any event the first layer element could advantageously be formed from welded metal wire.

In particular, the first layer element may include a lattice element.

It will also be appreciated that the second layer element may be formed with any of the above features and thus may be of identical, similar or different construction than the first layer element.

In such a manner, the first and second layer elements can be advantageously formed in a simple and relatively lightweight manner, facilitating transportation and construction.

To facilitate the adoption of the device of the present invention into use with slopes of various lengths and heights, a plurality of first layer elements may be arranged to join at the sides, or at the top and bottom edges thereof, to improve the rigidity of the complete slope support structure.

The first layer element can therefore advantageously be equipped with locking formations on a lower or upper edge region. In particular, the locking formations can include loops provided at the base of the first layer element.

The above-mentioned locking formations can advantageously be arranged for locking with said anchoring means and, in particular, they can be arranged to accommodate pivotal locking between two adjacent first layer elements.

The construction of a slope support structure can therefore be advantageously achieved in a relatively simple, safe and quick manner by the pivotal interlocking of each layer of the support structure one after the other.

Advantageously, the connecting means could comprise a planar element, which may also be rigid, perhaps more specifically in the form of a rigid mesh.

In order to achieve the same advantages as those that the first and second layer elements can exhibit, the connecting means can comprise a grid element formed of cold-drawn metal wire.

Advantageously, in practice, the connecting means and first and second layer elements can enclose a box-like structure without an upper and lower wall part.

In order to form a particularly advantageous rigid structure, said connecting means can be arranged to extend substantially perpendicularly to the first and/or second layer element.

To assist the ease with which the structure can be formed, the connecting means can advantageously be pivotally connected to the first and/or second layer element.

Furthermore, said device may advantageously include support means which serve to hold said connecting means at a desired angle of extension in relation to the first and/or second layer element.

The combination of the first layer element that snaps into the slope and the anchoring agent that extends into the slope surface provides an advantageously simple and effective support for the second layer element and thus for the layer of growth agent that can be placed between the first and second layer elements.

As mentioned above, the anchoring means may be arranged so that it can be arranged with the first layer element by a suitable pivotal formation formed on the first layer element.

The anchoring means has the advantage of allowing the use of soil reinforcement material which may include, for example, a geosynthetic material, geotextile, geogrid, or be in the form of a ladder-like arrangement of metal wires or in strips.

In another embodiment of the present invention, the anchoring means could comprise a soil nail and the locking formation formed on the first layer member could include a suitable socket for the soil nail.

According to a further advantage, the first layer element can be arranged with a soil separation membrane and the second layer element can be provided with a material layer for enhancing the plantable covering, such as a mat. The pivotal movement that can be provided between the second layer element and the connecting means readily facilitates the arrangement of any such mat element on the inner surface of the second layer element before that second layer element is pivotally arranged to close the side walls of the above-mentioned box-like structure.

The invention is particularly advantageous because the device can be easily packed flat and, depending on requirements, transported and constructed in a particularly quick and cost-effective manner.

It will be appreciated that the device may be readily incorporated onto a pre-existing slope surface or, alternatively, may be formed together with the slope so that, for example, the slope-forming material is readily compacted behind the first layer element during such construction.

According to a further aspect of the present invention, there is provided a method of forming a reinforced slope having a surface capable of supporting a plantable covering, comprising the steps of: strengthening the slope by providing in the slope reinforcing means extending rearwardly into the slope to reinforce the slope, assembling the first and second layer members in place so as to extend in the direction of the slope, wherein the second layer element is connected to the first layer element by means of connecting means in a manner that it extends in front of and is spaced from the first layer element, applying the growth medium in the region formed between said first layer element and said second layer element, and repeating the above steps with further first and second layer elements in order to provide the support for a plantable covering along the required length and height of the slope, characterized in that the method includes providing said first and second layer elements and the connecting means in the form of a rigid, box-like structure where the connecting means form the sides of the box-like structure, applying the growth medium in said region formed between the first and second layer elements by filling the growth medium through an open top end of the box-like structure and retaining the slope material by means of the first layer element, the first layer element being anchored to the slope by interlocking the first layer element with the reinforcing means in the slope.

Preferably, the connecting means is pivotally connected to the first layer element, and the second layer element is pivotally connected to the connecting means so that the first and second layer elements can be suitably attached to one another simply by pivotally arranging the connecting means and the layer elements as required.

A further advantage is that such a first layer element can engage with another underlying first layer element by performing a pivotal movement and due to the required interlocking between engagement formations of the respective first layer elements.

As will be appreciated, the present invention has the particular advantage that it can accommodate a thickness of growth medium, such as topsoil, which is suitable for the required greening as may prove particularly suitable and that the above-mentioned growth agent may be applied to the surface of any required slope in order to establish and maintain the green cover.

Furthermore, the growth medium can also be enhanced by the incorporation of water-retaining polymers and plant nutrients or soil improvers and this helps in the establishment and maintenance of the required green cover.

Embodiments of the invention are described below by way of example only, with reference to the accompanying drawings in which:

Figure 1 is a perspective view of a panel embodying the present invention;

Fig. 2 is a perspective view of the panel of Fig. 1 but shown in a folded condition;

Fig. 3 is a perspective view of the panel of Figs. 2 and 3 but in a fully unfolded state;

Fig. 4 is a view similar to Fig. 1, showing a plurality of panels during construction of a required slope; and

Figure 5 is a view of an apparatus similar to that shown in Figure 4 but according to another embodiment of the present invention.

In Fig. 1 there is shown a perspective view of a grid structure 10 embodying the present invention and including a first planar and metallic grid element 12 and a second planar and metallic grid element 14 spaced from the grid element 12 and located on a plane which is substantially parallel to the plane of the first grid member 12. A plurality of grid connectors 16 extend between the first 12 and second 14 grid members and serve to maintain the second grid member 14 in the required spaced relationship relative to the first grid member 12. (In the case of a soil nailing system described later with reference to Figure 5, connectors 116 are extended to interconnect the upper and lower layers of the grid structure.)

As can be appreciated from the discussion below, the first 12 and second 14 grid elements and the respective grid connecting elements 16 serve to form a generally box-like structure whose walls are formed by a metal grid but having open upper and lower ends.

Connecting loops 20, as will be appreciated from the following discussion, are arranged to engage an upper edge portion of another grid structure (not shown in Fig. 1) located beneath that illustrated in Fig. 1. In addition, the connecting loop 20 forms an anchor point from which an anchoring element 22 in the form of a layer of geosynthetic soil reinforcement material extends and which is secured to the connecting loop 20 with a soil reinforcement connecting rod 24, or alternatively to a reinforcement system of a ladder-like arrangement of metal meshes with a similar connecting loop 20 and using the connecting rod 24.

With respect to the general appearance of the grid structure 10, it will be appreciated that a linear channel region 26 is provided extending downwardly into the structure 10 and is defined by the first 12 and second 14 grid elements and the two opposing grid connecting elements 16.

Turning now to Figs. 2, 3 and 4, the construction of the lattice structure 10 illustrated in Fig. 1 will be further described.

In Fig. 2, the lattice structure 10 is shown in its collapsed state, which is a state in which the structure 10 can be transported to the required location and delivered in a particularly cost-effective manner. Each of the lattice connectors 16 is folded over the first lattice element 12, and the second lattice element 14 is also folded down to cover the lattice connectors 16 and the first lattice element 12.

In Fig. 3, the grid structure 10 is illustrated wherein the grid connecting elements 16 have been pivotally arranged in a position in which they extend in a perpendicular manner from the first grid element 12 and in which the second grid element 14 has been pivotally arranged in the same direction as the connecting elements to form the box-like structure 10.

It will be appreciated that in order to achieve the special shape of the lattice structure 10 shown in Fig. 3, starting from that shown in Fig. 2, the lattice connecting elements 16 have been arranged in a pivotable manner.

Wire straps (not shown) are provided and serve to hold the grid connecting elements 16 in a position in which they extend perpendicular to the first grid element 12. The pivotal movement is made possible by the provision of respective hinge means 30, 32 at the intersection between the grid connecting elements 16 and the first grid element 12, or the second grid element 19 and the grid connecting elements 16.

A matting material is applied to the inside of the second grid element 14 before the growing medium, for example suitable topsoil, is filled into the channel region 26 shown in Fig. 1.

The first and second grid elements 12, 14 can be advantageously connected by said connecting elements 16 in a manner that allows the pivotal movement of said connecting elements 16 from a flat-packed form to a fully assembled form as illustrated in Fig. 3.

In Fig. 4 there is shown a schematic drawing illustrating the application of a particular embodiment of the present invention. As will be appreciated, Fig. 4 shows a lattice structure corresponding to the structure of Figs. 1-3 defining an outer surface region of a slope for a dam being formed.

The current surface 34 of the embankment material 36 forming the actual embankment is illustrated as being provided at almost twice the height of a first grid element 12. Therefore, after the formation stage of the embankment as shown in Fig. 4, a embankment surface is formed and has so far reached the height of three stacked grid elements 10 (indicated at 10A, 10B and 10C) indicated by the three respective connecting loops 20 illustrated in the drawings (indicated at 20A, 20B and 20C). The two lower of the first grid elements 12 (indicated at 12A and 12B) have had the embankment material 36 therebehind compacted and at any appropriate stage the respective layer of anchoring material 22 (indicated at 22A and 22B) has been extended rearward into the embankment material 36 during its formation. Upon reaching the surface portion 34 now clear in Figure 4, a third grid element 10C has been stacked on top of the preceding grid structures 10B, 10A and this can be readily achieved by workers supported by the surface 34 and by simply pivotally connecting the connecting loop 20C associated with the third grid structure 10C into suitable engagement with an upper formation of the first grid element 12B of the second grid element 10B onto which it is to be stacked. Once in the position as shown in Figure 4, further embankment material ie onto the surface 34 as shown in Fig. 4 and compacted behind the first grid element 12C to increase the height of the embankment material. If the overall height of the embankment is to be greater than that illustrated in Fig. 4, then the process of stacking further grid structures 10 can be continued in the pivotal manner shown until the embankment reaches the required height.

As each grid structure 10 is stacked on top of the one below it, the channel 26 formed between the first 12 and second 14 grid elements of each grid structure 10 (see Figure 1) is filled with a suitable growth medium 38, for example a suitable topsoil. As previously mentioned with reference to Figure 3, the inner surface of the second grid element 14 has previously been lined with a matting material which can help to retain the growth medium 38 in the channel region 26.

As can then be appreciated, the desired vegetation cover introduced onto the slope surface now defined by every second grid element 14 can be advantageously established and maintained by the suitable growth medium comprising the layer 38 of growth medium now found in the channel region 26 while such growth medium is retained between the first 12 and second 14 grid elements. Since the vegetation cover need not establish itself in the compacted soil material 36 situated behind the grid structure 10 embodying the present invention, the vegetation cover suffers no detriment and, once established, can be readily maintained.

The particular box-like structure of the present invention is also advantageous in that a reasonably rigid and mechanically strong lattice structure can be provided which only requires that anchoring means 22 be extended into the embankment body to achieve the required mechanical strength.

Since the embodiment of the present invention illustrated in the drawings is formed of planar lattice elements, the angle at which the slope is to extend can be determined solely by on-site considerations rather than by factors such as the shape and relative dimensions of the lattice structure, as has often been the case with previous artificial structures.

Furthermore, in view of the rigid box-like structure, a separate structure such as rising closures is not necessary during the construction of the slope and particularly during compaction of the reinforced slope material 36. Therefore, it is possible to use larger compaction machines than otherwise known with the present invention. As can also be appreciated from Figures 1-4, the grid structure 10 is installed above the level of the required compaction work and this forms an advantageous safety barrier for the personnel on site.

Furthermore, the grid structure 10 is installed from the embankment side of the slope and by appropriate use of the connecting loop 20 it swings in front of the personnel and thus the protection of other site workers is maintained during the construction of the reinforced earth mass.

The use of the present invention therefore allows two distinct regions to be formed in the dam structure in which the main part of the dam may be formed from a reinforced mass of earth or any other inert material suitably compacted, while an outer layer of the surface region may be formed from a material suitable for the required vegetation cover.

Furthermore, the present invention does not require the incorporation of geosynthetic soil reinforcement materials, and thus the structure of the present invention does not suffer deterioration from ultraviolet rays. Geosynthetic Soil reinforcement materials can also suffer deterioration from elevated temperatures and thus the present invention also offers the advantage of avoiding such further causes of structural deterioration.

Furthermore, while the structural support of the surface of the reinforced mass is provided by the first grid element 12, the layer of growth agent within the grid structure 10 provides corrosion protection since direct exposure to corrosive elements can be advantageously avoided. Likewise, if a vehicle impact occurs against the grid structure 10, it is only the second grid element 14 and the layer of growth agent 38 that are damaged and the mechanical integrity of the slope-supporting grid structure remains intact.

Finally, the interlocking action between upwardly adjacent pairs of grid structures 10, which is advantageously achieved by the previously mentioned interlocking formations 20, provides positive interlocking between the elements forming the upper part of the complete structure and this therefore provides an effective structural restraint against pressures within the slope structure 36 during, and after, its compaction and construction.

Let us now turn to Figure 5, where another embodiment of the present invention is illustrated.

The grid structure 110 is somewhat similar to the grid structure illustrated with reference to Figures 1-4 in that it includes a first grid element 12, a second grid element 114, and a plurality of grid connecting elements 116 extending between the first grid element 112 and the second grid element 114.

Again, a suitable growing medium, for example, topsoil 138, is placed in the channel 126 formed between the first 112 and second 114 lattice members and serves to support the required vegetation cover. However, the embodiment of the present invention illustrated with reference to Figure 5 differs from that illustrated with reference to Figures 1-4 in that soil nails 122 which snap into the first lattice member 112 by means of a soil nail head plate 129 are used to anchor the lattice structure 110 into the slope material.

The embodiment of the present invention illustrated with reference to Figure 5 is particularly advantageous for use in the situation where the device of the present invention is to be supplied to the surface of an already existing slope. Therefore, an already existing slope formed of a generally organically inert material may advantageously be provided with a covering of suitable topsoil material 138 for the establishment and support of a vegetation cover. In addition, the use of soil nails allows an existing earth slope to be strengthened.

Although not limited to the above details, the illustrated embodiment of the present invention is formed from panels of rigid mesh which combine to form a box or cage-like structure and the meshes themselves are formed from cold drawn steel wire which has been electrically welded at each intersection and coated with benzal, galvanized or PVC coated. The infill growing medium which serves to form an area of an engineered reinforced soil system may comprise topsoil with soil additives such as a hydrous polymer, thickening and soil strengthening agents. In addition, seeded mats or mulch mats may be attached to the inner surface of the second mesh element 14 and this provides a grassed surface of the slope in the former case and a landscaped planted area in the latter case.

The embodiment illustrated with reference to Fig. 5 has the particular advantage that the device prevents so-called slumping around the soil nail head, which has been disadvantageous with structures used in the previous art and in particular with those in which geosynthetic materials were used.

As mentioned above, the device of the present invention provides a modular panel grid structure formed from panel parts which can be prefabricated with hinges for easy assembly on site and which can be conveniently stored and transported in flat-packed form.

In addition, a geosynthetic separation membrane can be applied to the rear surface of the first grid element 12 to prevent contamination of the growth medium and/or the reinforced soil.

The invention is not limited to the details of the above embodiments. For example, the grid structure 10 can be arranged to form any particular shape, and with the required number of connecting elements extending between the first and second grid elements. As such, the grid structure can be formed in situ, by appropriately connecting the required grid panels, rather than the mere rotational movement required by the illustrated embodiment.

Also, the grid elements may be formed of any material that can serve to form the channel to receive the growth medium appropriate to the conditions. For example, under special conditions, the first and second layer elements need not be planar or indeed rigid in shape.

It will be appreciated that other modifications and variations may be made to the embodiments described and are illustrated within the scope of the present application as defined by the appended claims.

Claims (24)

1. A method of forming a reinforced slope with a surface capable of supporting a plantable cover comprises the steps of: Reinforcing the slope (36) by providing reinforcing means (22; 122) in the slope, which extend backwards into the slope to reinforce the slope, assembling the first and second layer elements (12, 14; 112, 119) in position so that they extend in the direction of the slope (36), the second layer element (14; 114) is connected to the first layer element (12; 112) by connecting means (16; 116) in a manner to extend in front of and spaced from the first layer element (12; 112); Arranging the growth agent (38) in the region (26; 126) formed between said first layer element (12; 112) and said second layer element (14; 114); and Repeating the above steps with further respective first and second layer elements (12, 14; 112, 114) to support the green cladding along the required length and height of the slope (36); characterized by the fact that the method includes: providing said first and second layer elements (12, 14; 112, 114) and the connecting means (16; 116) in the form of a rigid, box-like structure (10; 110), the connecting means (16; 116) forming the sides of the box-like structure; disposing the growth agent (38) in said region (26; 126) formed between the first and second layer elements by filling the growth agent through an open upper end of the box-like structure (10; 110): and Retaining the embankment material (36) by means of the first layer element (22; 122), wherein the first layer element is anchored in the embankment by locking the first layer element with the reinforcing means (22; 122) in the embankment. 2. A method as claimed in claim 1, in which the connecting means (16; 116) forming the sides of the box-like structure are pivotally connected to the first and second layer elements (12, 14; 112, 114), and the method includes assembling the first and second layer elements (12, 14; 112, 114) and the connecting means (16; 116) by pivotal movement from a flat-packed folded state to the box-like structure (10; 110). 3. A method as claimed in claim 1 or 2, including: Construction of an embankment (36) by compacting a succession of earth layers one on top of the other; Locking, by a locking formation (20), a first layer element (12C) with another first layer element (12B) which is mounted at a lower level of the slope; and Installation of the upper first layer element (12C) by pivoting movement with the lower first Visible element (12B), the upper first layer element (12C) is connected by pivoting movement from the inner dam side (34) of the slope (36). 4. A method as claimed in any preceding claim, including reinforcing the slope by sheets of soil reinforcement materials extending into the slope between compacted layers of soil during construction of the slope. 5. A method as claimed in claim 1 or 2, including strengthening the slope by inserting soil nails into an existing slope. 6. Device for producing a green covering on a reinforced slope, comprising Reinforcing means (22; 122) extending rearward into the slope to reinforce the slope; a first layer element (12; 112) for extending over at least a portion of the slope (36); a second layer element (19; 114) for extending in front of said first layer element (12; 112) and which is mounted to be spaced therefrom so that a region (26; 126) can be provided therebetween for receiving the growth agent (38); and connecting means (16; 116) intended to establish the connection between said first and second layer elements (12, 19; 112, 119) when so arranged at spaced intervals; characterized by the fact that said first and second layer elements (12, 14; 112, 114) and the connecting means (16) are adapted to form a rigid, open-topped box-like structure, the connecting means (16; 116) forming the sides thereof, the box-like structure being adapted to provide, when in use, said region (26; 126) between the first and second layer elements as a channel region extending downwardly to receive the growth medium (38) which is filled into the box-like structure through an open top thereof; and the device includes means for engaging the first layer element (12; 112) with the reinforcing means (22; 122) so that when in use the reinforcing means also forms anchoring means for securing the device to the slope, the first layer element being adapted to retain the slope material when anchored by means of the reinforcing means. 7. Device as claimed in claim 6 in which the connecting means (16; 116) forming the sides of the box-like structure are pivotally connected to the first and second layer elements (12; 19; 112,114) to allow, by a pivotal movement, the assembly of the first and second layer elements (12, 14; 112, 114) and the connecting means (16; 116) from a flat-packed folded state to the box-like structure (10; 110). 8. A device as claimed in claim 6 or 7, wherein said first layer element (12; 112) comprises a substantially planar element. 9. Apparatus as claimed in claim 8, wherein said first layer member (12; 112) comprises a rigid mesh member. 10. Apparatus as claimed in claim 6, 7, 8 or 9, wherein said first layer element (12; 112) comprises a grid element. 11. Apparatus as claimed in any one of claims 6 to 10, wherein said second layer element (14; 114) comprises a substantially planar element. 12. Apparatus as claimed in claim 11, wherein said second layer member (14; 114) comprises a rigid mesh member. 13. Apparatus as claimed in any one of claims 6 to 12, wherein said second layer element (14; 214) comprises a grid element. 14. Apparatus as claimed in any one of claims 6 to 13, wherein said first layer element (12C) includes a locking formation (20C) for locking into another first layer element (12B) mounted at a lower level on the embankment (36) in operation, the locking formation (20C) allowing the apparatus to be installed in operation by pivotal movement of the upper first layer element (12C) relative to the lower first layer element (12B) from the inner embankment side (34) of the embankment (35). 15. Apparatus as claimed in claim 14, wherein said latching formation comprises a loop portion (20) at the periphery of the first layer member (12). 16. A device as claimed in claim 14 or 15, wherein said latch formation (20) is also adapted to latch with said reinforcing means (22) to form said latch means. 17. Device as claimed in any one of claims 6 to 16, wherein said connecting means (16; 116) comprises a planar element. 18. Device as claimed in claim 17, wherein said connecting element (16; 116) is formed of the same material as said first and second layer elements. 19. Device as claimed in any of claims 6 to 18, wherein said connecting means (16; 116) is arranged to extend perpendicularly to the first and/or second layer elements (12, 14; 112, 114). 20. Apparatus as claimed in any one of claims 6 to 19, wherein said reinforcing means is formed by a sheet of soil reinforcing material (22) for extending into the slope between compacted soil layers as the slope is constructed. 21. Apparatus as claimed in any one of claims 6 to 19, wherein said reinforcing means comprises a soil nail (122) for insertion into an existing slope. 22. Apparatus as claimed in any one of claims 6 to 21, wherein said first layer element (12) is provided on its rear surface with a soil separation membrane. 23. Device as claimed in any one of claims 6 to 22, wherein the second layer element (14; 114) is provided on its inner surface with a material layer for reinforcing the greening. 24. Device as claimed in any one of claims 6 to 23 when installed in a reinforced slope (36).