[0001] The present invention relates to the provision of adequate drainage by artificial
means and has particular application in the area of landscape gardening.
[0002] Known methods of draining relatively large surface areas where the funnelling of
water directly into narrow diameter pipes is impractical or impossible involve the
use of a layer of stone or gravel capable of supporting the surface to be drained.
Water from this "gravel" layer may then be allowed to percolate into the ground below,
follow the lie fo the land through said gravel to further conventional drainage channels
or pipes or otherwise evacuated. In the case of a roof-top garden for example a concrete
roof-top may be provided with a water impervious membrane opening into conventional
channels, gutters or drains; a layer of pebbles may the be provided over such membrane
followed by a filter membrane over such layer of pebbles over which filter membrane
a layer of soil is laid in which vegetation may be grown.
[0003] The filter membrane prevents the soil clogging the layer of pebbles thereby preventing
drainage; the layer of pebbles facilitates drainage of the soil and hence adequate
oxygen for the roots of vegetation. The lower impervious membrane in turn prevents
the ingress of moisture to the building or structure below.
[0004] Such a system as lastmentioned involving pebbles, gravel or stone has been found
to have various defects particularly in roof-top applications. The lastmentioned conventional
system may be expensive insofar as stones or pebbles are heavy thus presenting transportation
problems to high or inaccessible locations, the weight also may dictate otherwise
unnecessary reinforcement of the supporting structure. It has been further found that
where a water impervious membrane is employed below a layer of of pebbles the pebbles
often breach the water right integrity of such membrane due to sharp edges and/or
excessive weight. The conventional system as lastmentioned furthermore makes no provision
for the deployment of conduits for water or power through the drainage area particularly
where such conduits are to be laid after the drainage system is in existence. The
present invention seeks to ameliorate one or more of the lastmentioned disadvantages
with the prior art or at least provide the consumer with a choice.
[0005] According to the present invention there is provided a rigid cell structure comprising
first and second parallel perforate planar members maintained in a fixed spaced relationship
from each other by means of a plurality of spacer members of adequate strength to
ensure that either one of the perforate planar surfaces has a load bearing capability
of at least twenty kilograms per square metre when the opposing perforate planar surface
is supported by a rigid planar surface; the perforate nature of both surfaces and
the disposition of spacer members being such that gases or liquids may freely pass
through the cell structure around the spacer means in any direction.
[0006] The present invention also teaches a method of providing drainage utilising the lastmentioned
apparatus. In addition to roof-top garden applications it is envisaged that the invention
may be of use to provide drainage under roadways, under embankments and elsewhere
where surface erosion would otherwise be a problem.
[0007] One example of an article in accordance with the present invention will now be described
with reference to the accompanying drawings wherein:
Figure 1 is a part perspective view of a cell in accordance with the present invention;
Figure 2 is a further part perspective view of the cell of figure 1;
Figure 3 is a side elevation of the cell depicted in figures 1 and 2.
[0008] Figure 1 depicts a drainage cell comprising a first planar perforate surface 1 and
a second planar perforate surface 2 maintained in parallel spaced relationship to
each other by a plurality of upright spacer members 3.
[0009] The nature of perforations in the embodiment of figures 1 and 2 may best be observed
from figure 2 which clearly depicts substantially square perforate areas 4 in the
first planar surface 1. It will be noted that the square perforate areas are interposed
with substantially square load bearing sections 5 such that the resulting configuration
of the first planar surface 1 is checkered. In this embodiment the second perforate
planar surface is of the same configuration as the first perforate planar surface
except that the square perforate sections are out of register with each other such
that directly beneath each square perforate section of the first perforate planar
surface lies a square load bearing section of the second planar perforate surface.
[0010] It will be appreciated that a configuration as above described results in planar
surfaces having approximately fifty per cent of their surface area devoted to perforations
and the remaining fifty per cent devoted to a surface which is capable of load bearing.
In say a roof-top application where a membrane may be employed above the cell adjacent
the first perforate planar surface and possibly additionally beneath the cell it is
important that the load bearing surfaces comprise a significant proportion of the
planar surfaces in order that loads may be distributed. If this were not the case
then the cell might perforate adjacent membranes thereby destroying their effectiveness.
Where the cell is laid directly for example on a bitumenised roof (not shown) this
feature is particularly important as it would not be appropriate for the spacer members
3 to bear directly on the bitunenised surface thereby allowing perforation of the
bitumenised surface when a load was applied to the upper surface of the cell
[0011] It will be appreciated that the spacer members 3 are rectangular in confighration
and are (when viewed in transverse section)are oriented diagonally of the square pattern
associated with the planar surfaces so that the ends of such spacer members 6 form
bridges between adjacent load bearing surfaces thereby tying in adjacent load bearing
surfaces to each other and ensuring a coherent rigid structure.
[0012] Some bracing of the spacer members 3 is achieved by low upstanding walls 7 inwardly
directed from the planar perforate surfaces running between adjacent spacer members
and extending along the edges defining the square load bearing surfaces.
[0013] It will be noted that these small upstanding walls 7 define shallow areas 8 which
are capable of holding small amounts of pooled liquid. This is an important feature
where the cell is used for drainage of say a roof-top garden as during periods where
no water flow is present the water in such areas may evaporate thereby assisting to
maintain the roots of any plants or grass above the drainage cell in a moist condition
condusive to plant life.
[0014] Whilst it is envisaged that the primary function of the drainage cell will be to
accept water through its first and upper perforate planar surface and to allow free
percolation of the water through the cell towards a drain(not shown)beneath the cell
it should be appreciated that the cell additionally assists in maintaining oxygen
adjacent the roots of any plants above the upper planar surface. It should be noted
that the nature of the spacer members permits free flow of water and oxygen mary horizontal
direction within the cell and therefore it is usually not necessary to orient the
cell in any particular direction with respect to the fall of the surface over which
it is installed. The relatively open nature of the area between the two planar surfaces
additionally may provide space through which conduits may be passed for various services
which may be associated with a building.
[0015] Lines 8 depicts the possible directions for flow of water entering the upper surface
of the cell and flowing through the cell. The cell may advantageously be fabricated
from one of a number of plastic materials in a unitary configuration and in this regard
polypropelyene has been found to be appropriate.
[0016] The multiplicity of spacer members 3 together with walls 7 results in a relatively
rigid structure which is capable of supporting substantial loads and for example where
the spacer members are approximately thirty millimetres in length and three millimetres
by three millimetres in cross-section the load bearing capabilities of the upper planar
surface where the lower planar surface is supported on a concrete slab is approximately
38,000 kilograms per square metre.
[0017] The embodiment of figure 1 is approximately three hundred millimetres by three hundred
millimetres square and in order to cover a large surface a number of drainage cells
may be laid beside each other.
[0018] It should be appreciated that the present invention- provides a light drainage cell
which permits large volumes of water to be drained beneath a variety of surfaces and
may furthermore enhanced growth of vegetation above the cell.
[0019] Although it is not depicted herein those skilled in the art of drainage will note
that a filter membrane should be utilised above a cell in accordance with the present
invention due to the large apertures in the upper perforate planar surface and in
this regard"terraferma" brand polyester membranes are appropriate.
[0020] From figure 2 it may be observed that the edges of the drainage cell are not perfectly
straight but comprise a series of tongues 10 and grooves 11. These tongues and grooves
in the edges of one cell member facilitate a fairly precise location of adjacent cells
where cells are placed side by side so as to form a large mat. This is due ot the
fact that the tongues 10 of one cell will fit into the grooves 11 of an adjacent cell
thereby preventing relative horizontal movement between adjacent cells provided they
are urged towards each other. DATED this 3rd day of March, 1987.
1. A rigid cell structure comprising a first and second substantially parallel perforate
planar members maintained in a fixed spaced relationship from each other by means
of a plurality of spacer members; the perforate nature of both surfaces and the disposition
of spacer members being such that gases or liquids may freely pass through the composite
structure around the spacer means in any direction.
2. A structure in accordance with claim 1 wherein the perforate portions of the planar
surfaces comprise at least forty per cent of the total surface area.
3. A structure in accordance with any one of the preceding claims wherein at least
twenty per cent of the total surface area of the planar surfaces are adapted to support
a load.
4. A structure in accordance with claim 1 wherein the spacer members are columnar
in configuration and disposed substantially normally to the two parallel perforate
surfaces.
5. A structure in accordance with any one of the preceding claims wherein the perforate
areas are formed as parallelograms interposed with load bearing sections of like configuration
and dimensions in a checkered configuration; the spacer members being joined to the
perforate planar members adjacent the corners of such parallelogram shaped load bearing
sections and perforate areas.
6. A structure in"accordance with any one of the preceding claims wherein the perforate
areas are of a substantially square configuration interposed with substantially square
load bearing sections of similar dimensions in a checkered configuration; the spacer
members being joined to the perforate planar members adjacent the corners of such
square sections.
7. A structure in accordance with any one of the preceding claims wherein all perforate
areas of one perforate surface are out of register with the perforate areas of the
opposing perforate surface.
8. A structure in accordance with any one of the preceding claims where at least one
of the planar perforate surfaces includes upon its internally facing side a plurality
of low upstanding walls extending between adjacent spacer members defining shallow
areas adapted to trap small quantities of liquid.
9. A structure in accordance with any one of the preceding claims wherein the cell structure
is of adequate strength to ensure that either one of the perforate planar surfaces
has a load bearing capacity of at least twenty kilograms per square metre when the
opposing perforate planar surface is supported by a rigid planar surface.
10. A structure in accordance with any one of the preceding claims wherein the cell
structure is of adequate strength to ensure that either one of the perforate planar
surfaces has a load bearing capability of between 15,000 and 90,000 kilograms per
square metre when the opposing perforate planar surface is supported by a rigid planar
surface.
11. A rigid cell structure in accordance with any one of the preceding claims wherein
there is a regular pattern of shallow tongues and grooves along the peripheral edges
of the element to allow the elements to be interlocked when assembled into a mat.