GB2558832A - Improvements in and relating to drainage systems - Google Patents

Abstract

Storage and attenuation structure 10 for a drainage system, having upper layer 11 with fluid storage recesses 13 and openings 15 located above the storage recesses 13 to allow overflow fluid to drain, and lower layer 12 receiving fluid drained from upper layer 11 and having drainage pathways 14 to collect and drain the fluid received. Drainage pathways 14 are in fluid communication with space 17 between fluid storage recesses 13 such that said space 17 provides additional fluid storage capacity. A filter layer 19 may be provided. Structure 10 may be part of a drainage system supporting a growing medium, and sitting on a roof, for example a green roof. The layers 11, 12 may provide a drainage peak flow attenuation effect, and drainage pathways 14 may direct to an outflow controller. An outflow controller 100 is also described, having a flow controlling restrictor 110 and a drain component 120.

Description

(54) Title of the Invention: Improvements in and relating to drainage systems Abstract Title: Two layer fluid storage and drainage system (57) Storage and attenuation structure 10 for a drainage system, having upper layer 11 with fluid storage recesses 13 and openings 15 located above the storage recesses 13 to allow overflow fluid to drain, and lower layer 12 receiving fluid drained from upper layer 11 and having drainage pathways 14 to collect and drain the fluid received. Drainage pathways 14 are in fluid communication with space 17 between fluid storage recesses 13 such that said space 17 provides additional fluid storage capacity. A filter layer 19 may be provided. Structure 10 may be part of a drainage system supporting a growing medium, and sitting on a roof, for example a green roof. The layers 11, 12 may provide a drainage peak flow attenuation effect, and drainage pathways 14 may direct to an outflow controller. An outflow controller 100 is also described, having a flow controlling restrictor 110 and a drain component 120.

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Improvements in and relating to Drainage Systems

Field of the Invention

The present invention relates to storage and attenuation structures, for example such structures that may comprise part of drainage systems. The present invention further relates to outflow controllers, for example such controllers that may comprise part of drainage structures. Example embodiments are particularly suited for use in drainage systems for roofs, including green roofs.

Background to the Invention

One of the advantages of a green roof is the capacity of the roof to absorb rainwater and thereby reduce the peak flow of rainwater into subsequent drainage systems. This reduces the risk of flooding the subsequent drainage systems. The capacity to spread drainage load overtime contributes to a sustainable drainage system (often referred to as SUDS).

Problems arise when a green roof is not able to absorb rainwater as designed, for example if there are repeated heavy rainfall events in quick succession. In this situation the green roof may become saturated, which impacts on the SUDS performance. Building in additional capacity to cope with infrequent extreme rainfall events but without unduly increasing costs is a challenge.

In addition, controlling the rate of outflow from a green roof, and maintaining consistent outflow performance over the lifetime of the green roof poses problems, for example due to silting up of the drainage pathways in the green roof. Problems with the outflow can also impact on SUDS performance.

Furthermore, providing an outflow for a drainage system which is compatible with, and works effectively in any one of a range of different roof constructions is not straightforward.

Example embodiments of the present invention aim to address at least one disadvantage of the prior art, whether identified herein or otherwise.

Summary of the Invention

In one aspect, the present invention provides a storage and attenuation structure for a drainage system, the structure comprising:

an upper layer for supporting material above an upper side thereof, and including fluid storage recesses to collect and store fluid received from above the upper side thereof, and further comprising openings above the storage recesses to allow fluid communication between the upper side thereof and a lower side thereof such that overflow fluid from the storage recesses can drain through the openings; and a lower layer for receiving fluid drained from the upper layer, and including drainage pathways to collect and drain fluid received from the upper layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

Herein, the term fluid is to be understood as including any non-solid substance, for example liquids, gases, and combinations thereof. Similarly, “upper” and “lower” may be interchanged when the drainage system comprises a gas venting system, with other consequential changes to be understood.

Suitably, the lower layer comprises a substantially fluid impermeable component such that the drainage pathways are arranged to provide drainage to edges of the lower layer. Suitably, the upper layer comprises a sheet material. Suitably, the lower layer comprises a sheet material. In some embodiments the upper layer may rest on the lower layer. Suitably, a filter layer may be provided between the upper layer and the lower layer. In other embodiments the upper layer and lower may be attached to one another, for example formed as an integrated single component or formed as two components adhered, welded or otherwise coupled after separate manufacture. Suitably, the upper layer and lower layer extend over substantially the same area. Suitably, the lower and upper layers both comprise sheet materials. Suitably, the storage and attenuation structure comprises part of a drainage system, such that the upper layer supports a growing medium to be drained. Suitably, the storage and attenuation structure comprises part of a drainage system, such that the lower layer rests on a roof, for example on a waterproof membrane and/or insulation above structural elements of a building roof structure.

Suitably, the storage and attenuation structure is arranged with an outflow controller to control outflow from the drainage pathways of the lower layer.

Suitably, the drainage pathways are arranged to channel fluid in the plane of the sheet. Suitably, the drainage pathways are arranged to channel said fluid beyond the extent of the storage and attenuation structure. Suitably, the storage and attenuation structure is arranged to receive fluid from above and to channel said fluid to an edge or edge region thereof.

Suitably, the storage and attenuation structure is arranged to channel fluid to the outflow controller to discharge the fluid at a controlled rate.

Suitably, the upper and lower layers in use cooperate to provide a drainage peak flow attenuation effect, wherein in use the upper layer provides a volume for fluid storage within the storage and attenuation system, and wherein the lower layer provides a further volume to hold draining fluid when the storage recesses of the upper layer are filled, for example only when one, some or all of the storage recesses of the upper layer. Suitably, the outflow controller operates to control release of fluid from the storage and attenuation structure in a way which is principally dependent on the volume of fluid in the drainage pathways and in the space between the fluid storage recesses in the upper layer. Suitably, the outflow controller operates to control release of fluid from the storage and attenuation structure in a way which is independent on the volume of fluid in the storage recesses in the upper layer. Suitably, the storage and attenuation structure operates to provide an air gap between fluid stored in the storage recesses and fluid draining from the lower layer, such that static pressure from fluid in the upper layer is not relevant to the rate of release of fluid from the storage and attenuation structure.

Suitably, the storage recesses are of substantially similar shape to each other. Suitably, the storage recesses are distributed in regular arrangement across the upper layer. As will be appreciated, the storage recesses give the storage and attenuation structure a fluid storage capacity which is useful in providing moisture for vegetation growing on a green roof.

Suitably, the storage recesses are coupled at load-sharing grooves below the uppermost regions of the storage recesses, the load-sharing grooves arranged to enable fluid communication between adjacent storage recesses without the recesses overflowing to the level of the openings.

Suitably, one or more of the openings is at least partially surrounded by a border of material, the border of material being that which separates adjacent storage recesses.

Suitably, the openings are generally circular in shape. In other embodiments square drainage openings, or drainage openings of other regular or irregular shapes are envisaged. Suitably, the drainage openings are of substantially similar shape to each other. Suitably, the drainage openings are distributed in regular arrangement across the drainage material.

Suitably, the openings are arranged to allow fluid to from the storage recesses into a void between the upper and lower layers.

Suitably, the openings have a major dimension of less than 100mm across the upper layer. Suitably, the openings have a major dimension of greater than 2mm across the upper layer. Suitably, the openings have a diameter in the range 5mm to 25mm, preferably in the range 10 to 20mm, more preferably in the range 12-15mm.

Suitably, the upper layer is substantially fluid impermeable, other than at the openings. Suitably, the upper layer is made of a substantially fluid impermeable material and/or has a substantially fluid impermeable layer, other than at the openings. Suitably, the lower layer is made of a substantially fluid impermeable material and/or has a substantially fluid impermeable surface. Suitably, the upper and/or lower layer may each comprise a plastics material, preferably a HDPE material.

Suitably, the storage and attenuation structure further comprises a storage recess cover. Suitably, the storage recess cover comprises a fluid permeable material. Suitably, the storage recess cover is arranged in use to maintain growing medium and plant material away from the storage recesses and/or the openings. Suitably, the storage recess cover comprises a nonwoven textile, a woven textile or a combination thereof. Suitably, the storage recess cover comprises a plastics material. Suitably, the storage recess cover comprises a polypropylene material. Suitably, the storage recess cover comprises a long staple fibre material, a short fibre material, a continuous filament material, or a combination thereof.

Suitably, the fluid is water, or an aqueous solution.

Suitably, the storage and attenuation structure is suitable for use in a green roof system. Suitably, the storage and attenuation structure is suitable for supporting a growing medium above an upper side thereof.

In another aspect, the present invention provides a drainage system, for example a green roof drainage system incorporating the storage and attenuation structure described in relation to the above aspect.

In another aspect, the present invention provides a method of manufacturing a storage and attenuation structure, the method comprising providing an upper and lower layer together with one another, the upper layer including fluid storage recesses to collect and store fluid received from above the upper side thereof, and further comprising openings above the storage recesses to allow fluid communication between the upper side thereof and a lower side thereof such that overflow fluid from the storage recesses can drain through the openings; and the lower layer and including drainage pathways to collect and provide controlled drainage of fluid received from the upper layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, and the upper and lower layers are arranged such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

Suitably, the storage and attenuation structure is substantially as described in relation to the first aspect of the invention above, and operates in the ways described in relation to the first aspect of the invention above.

In another aspect the present invention provides a method of providing drainage using the storage and attenuation structure of the above aspect, or a drainage material manufactured according to the above aspect, the method comprising installing the storage and attenuation structure in a structure to be drained.

Suitably, the method comprises providing drainage fora roof.

Suitably, the method comprises covering the storage and attenuation structure with one or more of: growing medium; vegetation; ballast; paving.

Suitably, the method comprises arranging the storage and attenuation structure with an outflow controller.

In another aspect, the present invention provides an outflow controller comprising a first portion and a second portion, the first portion comprising a flow controlling restrictor and arranged to pass fluid received at the outflow controller through the flow controlling restrictor, and the second portion comprising a drain component arranged to receive fluid that has passed through the flow controlling restrictor and to channel that fluid as outflow.

Suitably, the flow controlling restrictor is formed as a structure comprising an inlet opening and an outlet opening. Suitably, the flow controlling restrictor comprises a channel between the inlet opening and the outlet opening. Suitably, the channel is within the first portion. Suitably, the channel between the inlet opening and outlet opening is open, such that if the outlet opening is blocked the channel may overflow, with overflow from the channel passing from the second portion as outflow. Suitably, the first and second portions are arranged such that overflow from the channel in use passes form the second portion as outflow in the same way as fluid which passes through the outlet opening of the flow controlling restrictor. Suitably, the channel may comprise overflow openings positioned below the top thereof, to enable overflow from the channel before the channel is filled. Suitably, the flow controlling restrictor comprises a filter element arranged between the inlet opening and the outlet opening. Suitably, the filter element comprises a two-stage, or other multi-stage filter. Suitably, the channel, and the filter it may contain, is arranged to be accessible from an inspection opening in the first portion. Suitably, the flow controlling restrictor comprises a plurality of inlet openings. Suitably, the flow controlling restrictor comprises a main outlet opening. Suitably, the flow controlling restrictor comprises a plurality of main outlet openings, for example 2, 4 or up to 10 main outlet openings. Suitably, one or more of the main outlet openings is provided in the form of an adjustable opening. Suitably, the main outlet opening, or each of a plurality of outlet openings is provided in the form of an adjustable opening.

Suitably, the second portion comprises an insulation-interfacing region arranged to interface with an insulation layer in use with the outflow controller. Suitably, the insulation-interfacing region comprises a lip under which insulation is in use received. Suitably, the insulationinterfacing region comprises a space between a lip and a flange, into which insulation is in use received. Suitably, the flange is arranged to sit above a fluid-impermeable layer. Suitably, the second portion comprises one or more seepage slots, for example in the flange or at a bottom region, for example a lowermost region thereof.

Suitably, the lip is arranged to provide a collection surface to guide fluid received at the outflow controller to the first portion. Suitably, the lip comprises a collection channel to hold fluid received at the outflow controller in the region of the first portion. Suitably, the lip comprises a blocking portion which is arranged to inhibit passage of fluid received at the outflow controller between the second portion and the outflow.

Suitably, the first portion comprises part of a first component and the second portion comprises part of a second component. Suitably, the first and second components are separate components coupled to one another in the outflow controller.

Suitably, the first component is coupleable to any one from a range of second components of differing dimensions, in order to provide an outflow controller that is effective in interfacing with insulation layers of a corresponding range of dimensions.

Suitably, the second component is arranged to interface at an outer region with the first component and fluid received at the first component, and to interface at an inner region with the first component and fluid that has passed through the flow controlling restrictor.

In some embodiments, the flow controlling restrictor comprises a seepage opening arranged to work with a main outlet opening to enable a small amount of seepage to take place through the flow controlling restrictor. In some embodiments, the flow controlling restrictor comprises a sump area arranged below the main outlet opening(s), arranged to collect particles from fluid as it flows from the inlet opening to a main outlet opening. Suitably, the sump area is provided as part of the channel, for example the lower part, or lowermost part of the channel. Suitably, the main outlet opening, and any adjustable opening it contains, is arranged to be accessible from an inspection opening in the first portion. Suitably, the inspection opening is provided with a closure, which when closed provides a fluid impermeable seal between the outside of the first portion and the inside. Suitably, the inlet opening offers a smaller restriction to flow than the outlet opening. Suitably, in the flow controlling restrictor the inlet opening is less restrictive to flow than the outlet opening, for example such that the inlet causes a negligible restriction to flow.

Suitably, the first portion comprises an overflow conduit that provides a fluid communication path between the outside of the flow controlling component and a drain component, wherein the overflow conduit is arranged above the flow controlling restrictor.

In another aspect, the present invention provides a first portion of an outflow controller, the first portion comprising a flow controlling restrictor and arranged to pass fluid received at the outflow controller through the flow controlling restrictor, and comprising a drain component arranged to receive fluid that has passed through the flow controlling restrictor and to channel that fluid as outflow.

Suitably, the first portion is substantially as described in relation to the outflow controller of the aspect of the invention set out above.

In another aspect, the present invention provides a kit of parts for providing a drainage system, the kit comprising a first component of an outflow controller; and a storage and attenuation structure for assembly into a drainage system. Suitably, the kit further comprises a second component of an outflow controller arrangeable with the first component to provide the outflow controller. Suitably, the storage and attenuation structure is substantially as described in relation to any one of the aspects of the invention above. Suitably, the outflow controller is substantially as described in relation to any one of the aspects of the invention set out above.

In another aspect, the present invention provides a drainage system made up from the components of the kit described in relation to the aspect of the invention set out above.

Brief Introduction to the Drawings

For a better understanding of the invention, and to show how embodiments of the same may be carried into effect, reference will now be made, by way of example, to the accompanying diagrammatic drawings in which:

Figure 1 shows a side section view of a storage and attenuation structure according to an example embodiment, and an outflow controller according to an example embodiment, arranged together in a drainage system according to an example embodiment;

Figure 2 shows a side section view of the storage and attenuation structure of Figure 1, and an outflow controller according to another example embodiment, arranged together in a drainage system according to an example embodiment;

Figures 3A-3E show perspective, elevation and sectional views of a first portion of an outflow controller according to an example embodiment; and

Figures 4A-4E show perspective, elevation and sectional views of a second portion of an outflow controller according to an example embodiment.

Description of Example Embodiments

Figure 1 shows a side section view of a storage and attenuation structure 10 in use with an outflow controller 100. Together the storage and attenuation structure 10 and outflow controller 100 form part of a green roof structure which is provided above the structural elements of the roof R of a building. The green roof structure comprises vegetation V and a growth medium G. The roof R comprises a drain D to carry away excess rainwater from the green roof, after passage through the storage and attenuation structure 10 and the outflow controller 100. Also shown in Figure 1 is insulation material for the roof, denoted as I, and which is provided in position which is above a fluid-impermeable membrane M so as to form what is referred to as in inverted green roof configuration. In this inverted green roof a further breathable, waterproof membrane 18 is provided to give a further degree of water resistance to the overall roof structure, and to enable any moisture which finds its way into the insulation, e.g. on installation before the insulation is overlaid, to permeate out.

The storage and attenuation structure 10 is arranged to perform a number of functions. Firstly, it provides fluid storage, so that the growth medium G can be kept moist for longer and therefore providing better conditions for the vegetation V during periods where not much rain falls. Herein, the term fluid is generally to be understood as including any non-solid substance, for example liquids, gases, and combinations thereof, but in typical green roof applications the fluid will comprise water such as rain water, melt-water or the like. In addition to the storage of fluid to keep the growth medium G moist, the storage and attenuation structure 10 provides a SUDS function by buffering excess fluid and allowing that fluid to subsequently pass into the drain D over a relative longer period of time than if no storage or attenuation structure 10 was provided.

The storage and attenuation structure 10 comprises an upper layer 11 for supporting the growth medium G above an upper side thereof. Growth medium G is kept above the upper layer 11 by a fluid-permeable barrier layer 19. The upper layer 11 comprises fluid storage recesses 13 to collect and store fluid received from above the upper side of the upper layer 11. The fluid storage recesses 13 in the example embodiment of Figure 1 are in the form of downward pointing, truncated square-based pyramidal recesses, which are provided in regular arrangement across the surface of the sheet-like upper layer 11. Between the fluid storage recesses 13 are openings 15, formed is a border of material separating adjacent storage recesses 13. The openings 15 are circular, and an opening 15 is provided at each corner of each of the fluid storage recesses 13. The fluid-permeable barrier layer 19 serves to keep the openings 15 clear of growth medium G.

The openings 15 are formed above the fluid storage recesses 13 in order to allow fluid communication between the upper side of the upper layer 11 and a lower side thereof. In this way, the vast majority of any rain water which passes down through the vegetation V and growth medium G is initially collected in the fluid storage recesses 13. Any overflow fluid from the storage recesses 13 can drain through the openings 15 and into a lower layer 12 of the storage and attenuation structure 10.

The lower layer 12 receives fluid from the upper layer 11, and includes drainage pathways 14 to collect fluid received from the upper layer 11 and provide controlled drainage of that fluid. The drainage pathways 14 are formed between projections in the lower layer 12. The drainage pathways 14 are in fluid communication with space 17 between the fluid storage recesses 13 in the upper layer, such that the space 17 between the fluid storage recesses 13 provides additional fluid storage capacity beyond the capacity of the lower layer 12. In this way, when the drainage pathways 14 are filled to the level of the top of the lower layer 12, for example after a period in which when the rate of supply of fluid through the openings 15 exceeds the rate of drainage from the drainage pathways 14, the space 17 provides additional capacity storage capacity in the storage and attenuation structure 10 so that the peak flow from the storage and attenuation structure 10 is still smoothed. By using the space between the storage recesses 13 in this way, the storage and attenuation structure 10 can be made inexpensively from existing types of drainage layers, and offers improved performance in case of the type of infrequent, but increasingly important extreme rainfall events.

The rate at which fluid may drain from the drainage pathways 14 is controlled by the outflow controller 100, as described in more detail below.

In the embodiments shown in Figure 1, the upper layer 11 and the lower layer 12 are separated by a fluid-permeable layer 16, with the compressive weight of the growth medium G and the vegetation V enough to hold the layers together. In example embodiments the fluidpermeable layer 16 may comprise a filter layer. However, it will be understood that in other embodiments the layers may be formed as an integrated single component or formed as separate components adhered, welded or otherwise coupled to one another after separate manufacture, with or without an intermediate layer. In another variation, not shown, the storage recesses 13 in the upper layer 11 are coupled to their neighbours by load-sharing grooves arranged below the uppermost regions of the storage recesses, the load-sharing grooves arranged to enable fluid communication between adjacent storage recesses without the recesses overflowing to the level of the openings 15.

The outflow controller 100 operates to control release of fluid from the storage and attenuation structure 10 in a way which is principally dependent on the volume of fluid in the drainage pathways 14 and in the space 17 between the fluid storage recesses 13 in the upper layer 11.

Still referring to Figure 1, the outflow controller 100 shown is made up of a first portion 110 and a second portion 120. The first portion 110 comprises a flow controlling restrictor is and arranged to pass fluid received at the outflow controller through the flow controlling restrictor. The second portion 120 comprises a drain component arranged to receive fluid that has passed through the flow controlling restrictor and to channel that fluid as outflow. In figure 1 the first and second portions 110, 120 are shown slightly separated for explanatory purposes. In use the first and second portion 110, 120 are coupled at a connector 112.

By providing the first and second portions as separate components, referred to hereinafter as the first and second components 110, 120 respectively, a single-pattern first component 110 can be supplied to be coupled to any one from a range of second components 120 of differing dimensions. This way, manufacturing costs for the outflow controller 100 can be reduced without impacting on the ease of installation in different drainage systems. For example, as will be explained in more detail below, the second component 120 passes through an opening the insulation I, and must allow the outflow controller 100 to interface effectively with the drain D, insulation I and the elements above the insulation I from which drainage is required. In this case, differing depths of insulation required for particular installations may be accommodated by selecting a second component of suitable height between its base and the level of the edge of a layer to be drained. It should be noted that although the outflow controller 100 has been shown in use with the storage and attenuation structure described above, it will be appreciated that the outflow controller 100 may also be usefully employed in combination with other, for example, related-art storage and attenuation components or drainage components. The roof structure in Figures 1 and 2 comprises an inverted green roof, but the growth medium and vegetation of the green roof may be substituted for ballast, paving etc in other roof structures, and the outflow controllers, and storage and attenuation structures described herein may equally find useful application in such roofs.

Furthermore, the single-pattern first component 110 can be used in warm roof installations, in which the roof to be drained is insulated from below, within the structural elements of the roof structure, without the need for a second component 120. This, in one aspect of the invention there is provided a first component comprising features as described herein, useful either in combination with a second component as described herein, or in combination with a roof drainage structure in which the first component cooperates directly with, for example rests on the roof surface to be drained.

The second component 120 is arranged to interface, at its outer region, with the first component 110, and with fluid received at the first component 110. The second component 120 is also arranged to interface, at its inner region, with the first component 110 and fluid that has passed through a flow controlling restrictor of the outflow controller 100. This enables the outflow controller 100 to give consistent fluid control performance, by using the second component 120 as part of the path into the outflow controller while separating the operation of the flow controlling restrictor from direct influence of the inlet to the outflow controller and the outlet of the outflow controller.

The second component 120 comprises an insulation-interfacing region 122 arranged to interface with the insulation I. The insulation-interfacing region 122 comprises a lip 124 under which the insulation I is received. The insulation-interfacing region 122 comprises a flange 126, and the insulation is received in the space there-between. The flange 122 sits above the fluid-impermeable membrane M. There is detail of this feature shown in the isometric detail insert A, where seepage slots 127 are shown. The seepage slots 127 are provided to enable moisture which does pass into the insulation I to escape under gravity. Also shown in Figure 1 and 2 is a ledge 134, which is formed on the first component 110 and is useful to keep the growth medium G out of the upper layer 11. The fluid-permeable barrier layer 19 which lies above the upper layer 11 can overlay the ledge 134 and be joined there-to, for example by adhesive, to block growth medium G from entering the upper layer 11 around the edge of the fluid-permeable barrier layer 19.

The lip 124 provides a collection surface to guide fluid received at the outflow controller 100 to the first component 110 and thereby into the flow controlling restrictor. As shown in Figure 1, the lip 124 comprises a collection channel 128 to hold fluid received at the outflow controller 100 in the region of the first component 110. Also shown, in dotted lines, is a variation in which the lip comprises a blocking portion 124’ arranged to inhibit passage of fluid received at the outflow controller 100, through the connection between the second component 120 and the first component 110.

The outflow controller 100 works to restrict passage of fluid from above the insulation layer to the drain D by employing a flow controlling restrictor. The flow controlling restrictor is formed as a structure comprising an inlet opening 114 and an outlet opening 116. Between the inlet opening 114 and the outlet opening 116 is a channel 118. The channel 118 is formed within the first component 110 and receives fluid which has passed into the first component 110 from the inlet opening 114. In the embodiments shown, the outlet opening 116 operates to provide the controlled outflow from the second component.

The channel 118 between the inlet opening 114 and outlet opening 116 is open, such that if the outlet opening 116 is blocked for whatever reason, the channel 118 can still overflow, with overflow from the channel 118 passing from the first component 110 to the second component 120 and then from the second component 120 as outflow to the drain D. The channel 118 shown in Figure 1 comprises overflow openings 119 positioned below the top of the channel 118 to enable overflow from the channel 118 before the channel is filled. However, it is advantageous for the level of the top of the channel 118, or any overflow openings to be arranged above the level at which static pressure can cause fluid to overflow the channel, meaning that in normal use the outlet opening 116 drains all of the fluid there-through, and the rate control provided by the flow controlling restrictor is dictated by the outlet opening 116.

In the channel 118, a filter 113 is provided arranged between the inlet opening 114 and the outlet opening 116. The channel 118, and the filter 113 it contains are accessible from an inspection opening in the first component 110. As shown in Figure 1 the inspection opening is sealed by a lid 117. The lid 117 is removable and re-sealable onto the first component 110 so as to enable the filter 113 and channel 118 to be inspected and replaced/cleaned as necessary. Using the filter 113 as a secondary filtration element, after fluid is primarily filtered by the fluid-permeable layer 16, or the fluid-permeable layer 16 in combination with a fluidpermeable barrier layer 19 can give good filtration performance, down to particle sizes as low as 80-100 micrometres. The filter material and type are selected to give the required performance, according to requirements of the particular installation, for example in terms of porosity, flow rate, compatibility, efficiency, capacity etc. Furthermore, the channel 118 provides a sump area below the level of the outlet opening 116. This sump area acts as a silt trap for any larger particles which have passed into the flow controlling restrictor. The sump area serves to collect particles rather than allow them to pass out of the flow controlling restrictor. The sump area can be easily inspected for the presence of trapped silt, which is useful in identifying that there may be a problem in the installation. Furthermore the sump area can be easily accessed for cleaning if silt build-up is taking place.

Figure 1 shows an outflow controller 100 in which the flow controlling restrictor comprises a plurality of inlet openings 114. In this embodiment the inlet openings are numerous and sufficient that they do not cause a significant restriction in fluid flow. However, the flow controlling restrictor comprises a more limited outlet opening 116, illustrated in Figure 1 by two main outlet openings 116. The outflow controller 100 of Figure 1 is of generally rectangular section, when viewed in plan, with one main outlet opening per side to give four main outlet openings. In typical installations that are envisaged for the outflow controller a plurality of outflow openings, for example two, or ten or more may be provided.

The outlet openings 116 are provided in the form of an adjustable opening, which can be varied in effective size, for example by a simple threaded stopper or other variable obstruction held there-in. In this way, adjustment of the outlet opening 116 can be used to vary the flow rate from the outflow controller 100. For example, in an initial installation a maximum nominal flow rate of 2.5 litres/second for each hectare to be drained may be specified. However, if environmental or other conditions change after installation it is possible to adjust the outlet opening to vary the flow rate, for example to reduce the maximum nominal flow rate down to 2 litres/second for each hectare to be drained. Typical outlet openings may be in the region of a few millimetres in diameter, up to 20mm or more. In other examples the adjustable opening may comprise a movable slide, flap or iris-diaphragm that can provide a variable obstruction to the opening, or may comprise a replaceable swap-in/swap-out restrictor in which opening component can be easily replaced with another with a larger or smaller effective restriction as required.

As with the filter 113 and channel 118, the main outlet openings 116 are accessible through the inspection opening, for example to enable the adjustable opening to be maintained or adjusted.

Finally in respect of Figure 1, there is shown an overflow conduit 115 that provides a fluid communication path between the outside of the outflow controller and the drain D. The overflow conduit is at the level of the vegetation V to facilitate drainage thereof in the event of a blockage there-below, or in case of an exception extreme rainfall event.

Figure 2 shows the storage and attenuation structure of Figure 1, and an outflow controller 200 according to another example embodiment, arranged together in a drainage system. In contrast to Figure 1, where the drain D is central and the outflow controller 100 surrounds the drain D passing through the insulation I and the other layers, Figure 2 shows the outflow controller 200 at the edge of a roof R coupled to an edge drain D’. There are some modifications to the first and second components 210, 220 of the outflow controller 200, as compared to the corresponding elements shown in Figure 1, particularly in incorporating wall of the first component 210 as an interface with the edge drain D’. There is detail of this modification shown in the isometric detail insert B, in which slots are provided in the wall of the first component 210 to enable fluid to pass from the first component 210 into the drain D’.

Figures 3A-3E show perspective, elevation and sectional views of a first portion 310 of an outflow controller, that is arranged to work in cooperation with a second portion 320 of an outflow controller as shown in Figures 4A-4E to form an outflow controller 300 according to another example embodiment. The region indicated 312 in these figures serves as the connection between the first and second portions 310, 320. In this embodiment there are shown limited inlet openings 314 and a channel 318 to perform the function of the flow controlling restrictor.

Although the embodiments described herein are intended for drainage of water (which herein includes aqueous based solutions as well as pure H₂O) from a green roof, other related embodiments can also be envisaged as suitable for draining other fluids, including gasses, from other media and in other situations. In relation to drainage of water in a green roof, the drainage system may also be usefully employed under block paving, car park decks or alternatively as a SUDS layer in the ground.

Attention is directed to all papers and documents which are filed concurrently with or previous to this specification in connection with this application and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated herein by reference.

All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive.

Each feature disclosed in this specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.

The invention is not restricted to the details of the foregoing embodiment(s). The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.

The invention may be defined by the following examples:

1. A storage and attenuation structure for a drainage system, the structure comprising:

an upper layer for supporting material above an upper side thereof, and including fluid storage recesses to collect and store fluid received from above the upper side thereof, and further comprising openings above the storage recesses to allow fluid communication between the upper side thereof and a lower side thereof such that overflow fluid from the storage recesses can drain through the openings; and a lower layer for receiving fluid drained from the upper layer, and including drainage pathways to collect and drain fluid received from the upper layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

2. The storage and attenuation structure of example 1, wherein the lower and upper layers both comprise sheet materials.

3. The storage and attenuation structure of example 1 or 2, wherein a filter layer is provided between the upper layer and the lower layer.

4. The storage and attenuation structure of any preceding example, comprising part of a drainage system such that the upper layer supports a growing medium to be drained, and such that the lower layer rests directly, or indirectly on a roof.

5. The storage and attenuation structure of any preceding example, wherein, the upper and lower layers in use cooperate to provide a drainage peak flow attenuation effect, wherein in use the upper layer provides a volume for fluid storage within the storage and attenuation system, and wherein the lower layer provides a further volume to hold draining fluid when the storage recesses of the upper layer are filled.

6. The storage and attenuation structure of any preceding example, wherein the storage and attenuation structure is arranged with an outflow controller to control outflow from the drainage pathways of the lower layer.

7. The storage and attenuation structure of example 6, wherein the drainage pathways are arranged to channel fluid to the outflow controller to discharge the fluid at a controlled rate.

8. The storage and attenuation structure of example 6 or 7, wherein the outflow controller operates to control release of fluid from the storage and attenuation structure in a way which is principally dependent on the volume of fluid in the drainage pathways and in the space between the fluid storage recesses in the upper layer.

9. The storage and attenuation structure of example 6, 7 or 8, wherein the outflow controller operates to control release of fluid from the storage and attenuation structure in a way which is independent on the volume of fluid in the storage recesses in the upper layer.

10. The storage and attenuation structure of any preceding example, wherein the storage and attenuation structure operates to provide an air gap between fluid stored in the storage recesses and fluid draining from the lower layer, such that static pressure from fluid in the upper layer is not relevant to the rate of release of fluid from the storage and attenuation structure.

11. The storage and attenuation structure of any preceding example, wherein one or more of the openings is at least partially surrounded by a border of material, the border of material being that which separates adjacent storage recesses.

12. The storage and attenuation structure of any preceding example, wherein the openings are arranged to allow fluid from the storage recesses into a void between the upper and lower layers.

13. The storage and attenuation structure of any preceding example, further comprising a storage recess cover, provided as a fluid permeable material arranged in use to maintain growing medium and plant material away from the storage recesses and/or the openings.

14. A drainage system, comprising a green roof drainage system incorporating the storage and attenuation structure described in any one of examples 1 to 13.

15. A method of providing drainage using the storage and attenuation structure of any one of examples 1 to 13, the method comprising installing the storage and attenuation structure in a structure to be drained.

16. A method of manufacturing a storage and attenuation structure, the method comprising providing an upper and lower layer together with one another, the upper layer including fluid storage recesses to collect and store fluid received from above the upper side thereof, and further comprising openings above the storage recesses to allow fluid communication between the upper side thereof and a lower side thereof such that overflow fluid from the storage recesses can drain through the openings; and the lower layer and including drainage pathways to collect and provide controlled drainage of fluid received from the upper layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, and the upper and lower layers are arranged such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

17. An outflow controller comprising a first portion and a second portion, the first portion comprising a flow controlling restrictor and arranged to pass fluid received at the outflow controller through the flow controlling restrictor, and the second portion comprising a drain component arranged to receive fluid that has passed through the flow controlling restrictor and to channel that fluid as outflow.

18. The outflow controller of example 17, wherein the flow controlling restrictor is formed as a structure comprising an inlet opening and an outlet opening, with an open channel between the inlet opening and the outlet opening, arranged such that if the outlet opening is blocked the channel may overflow, with overflow from the channel passing from the second portion as outflow.

19. The outflow controller of example 18, wherein the channel comprises one or more overflow openings positioned below the top thereof, to enable overflow from the channel before the channel is filled.

20. The outflow controller of example 17, 18 or 19, wherein the flow controlling restrictor comprises a filter element arranged between the inlet opening and the outlet opening

21. The outflow controller of example 18, 19 or 20, wherein the channel, and/or filter are arranged to be accessible from an inspection opening in the first portion.

22. The outflow controller of any one of examples 17 to 21, comprising one or more main outlet openings, with one of more of the main outlet openings provided in the form of an adjustable opening.

23. The outflow controller of any one of examples 17 to 22, wherein the second portion comprises an insulation-interfacing region arranged to interface with an insulation layer in use with the outflow controller, the insulation-interfacing region comprising a lip under which insulation is in use received.

24. The outflow controller of example 23, wherein the insulation-interfacing region comprises a space between a lip and a flange, into which insulation is in use received.

25. The outflow controller of example 24, wherein the lip is arranged to provide a collection surface to guide fluid received at the outflow controller to the first portion.

26. The outflow controller of any one of examples 17 to 25, wherein the first portion comprises part of a first component and the second portion comprises part of a second component, the separate coupled to one another in the outflow controller.

27. The outflow controller of example 26, wherein the first portion comprises an overflow conduit that provides a fluid communication path between the outside of the flow controlling component and a drain component, wherein the overflow conduit is arranged above the flow controlling restrictor.

28. The outflow controller of example 26 or 27, wherein the second component is arranged to interface at an outer region with the first component and fluid received at the first component, and to interface at an inner region with the first component and fluid that has passed through the flow controlling restrictor.

29. The outflow controller of any one of examples 17 to 28, wherein the flow controlling restrictor comprises a seepage opening arranged to work with a main outlet opening to enable a small amount of seepage to take place through the flow controlling restrictor.

30. The outflow controller of any one of examples 17 to 29, wherein the flow controlling restrictor comprises a sump area arranged below main outlet opening(s), arranged to collect particles from fluid as it flows from the inlet opening to a main outlet opening.

31. The outflow controller of any one of examples 17 to 30, wherein the main outlet opening, and any adjustable opening it contains, is arranged to be accessible from an inspection opening in the first portion.

32. The outflow controller of any one of examples 17 to 31, wherein the inlet opening is less restrictive to flow than the outlet opening, for example such that the inlet causes a negligible restriction to flow.

33. A kit of parts for providing a drainage system, the kit comprising a first component of an outflow controller; and a storage and attenuation structure as claimed above, for assembly into a drainage system.

34. A drainage system, storage and attenuation structure or outflow controller substantially as herein described, with reference to the accompanying drawings.

Claims (11)

Claims:

1. A storage and attenuation structure for a drainage system, the structure comprising:

an upper layer for supporting material above an upper side thereof, and including fluid storage recesses to collect and store fluid received from above the upper side thereof, and further comprising openings above the storage recesses to allow fluid communication between the upper side thereof and a lower side thereof such that overflow fluid from the storage recesses can drain through the openings; and a lower layer for receiving fluid drained from the upper layer, and including drainage pathways to collect and drain fluid received from the upper layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

2. The storage and attenuation structure of claim 1, wherein the lower and upper layers both comprise sheet materials.

3. The storage and attenuation structure of claim 1 or 2, wherein a filter layer is provided between the upper layer and the lower layer.

4. The storage and attenuation structure of any preceding claim, comprising part of a drainage system such that the upper layer supports a growing medium to be drained, and such that the lower layer rests directly, or indirectly on a roof.

5. The storage and attenuation structure of any preceding of claim, wherein, the upper and lower layers in use cooperate to provide a drainage peak flow attenuation effect, wherein in use the upper layer provides a volume for fluid storage within the storage and attenuation system, and wherein the lower layer provides a further volume to hold draining fluid when the storage recesses of the upper layer are filled.

6. The storage and attenuation structure of any preceding of claim, wherein the storage and attenuation structure is arranged with an outflow controller to control outflow from the drainage pathways of the lower layer.

7. The storage and attenuation structure of claim 6, wherein the drainage pathways are arranged to channel fluid to the outflow controller to discharge the fluid at a controlled rate.

8. The storage and attenuation structure of claim 6 or 7, wherein the outflow controller operates to control release of fluid from the storage and attenuation structure in a way which is principally dependent on the volume of fluid in the drainage pathways and in the space between the fluid storage recesses in the upper layer.

9. The storage and attenuation structure of claim 6, 7 or 8, wherein the outflow controller operates to control release of fluid from the storage and attenuation structure in a way which is independent on the volume of fluid in the storage recesses in the upper layer.

10. The storage and attenuation structure of any preceding claim, wherein the storage and attenuation structure operates to provide an air gap between fluid stored in the storage recesses and fluid draining from the lower layer, such that static pressure from fluid in the upper layer is not relevant to the rate of release of fluid from the storage and attenuation structure.

11. A method of manufacturing a storage and attenuation structure, the method comprising providing an upper and lower layer together with one another, the upper layer including fluid storage recesses to collect and store fluid received from above an upper side of the upper

15 layer, and further comprising openings above the storage recesses to allow fluid communication between the upper side and a lower side of the upper layer such that overflow fluid from the storage recesses can drain through the openings; and the lower layer and including drainage pathways to collect and provide controlled drainage of fluid received from the upper layer, wherein the drainage pathways are formed

20 between the projections in the lower layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, and the upper and lower layers are arranged such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

Intellectual

Property

Office

Application No: GB1806094.7 Examiner: Mr Tom Simmonds

11. The storage and attenuation structure of any preceding claim, wherein one or more of the openings is at least partially surrounded by a border of material, the border of material being that which separates adjacent storage recesses.

12. The storage and attenuation structure of any preceding claim, wherein the openings are arranged to allow fluid from the storage recesses into a void between the upper and lower layers.

13. The storage and attenuation structure of any preceding claim, further comprising a storage recess cover, provided as a fluid permeable material arranged in use to maintain growing medium and plant material away from the storage recesses and/or the openings.

14. A drainage system, comprising a green roof drainage system incorporating the storage and attenuation structure described in any one of claims 1 to 13.

15. A method of providing drainage using the storage and attenuation structure of any one of claims 1 to 13, the method comprising installing the storage and attenuation structure in a structure to be drained.

16. A method of manufacturing a storage and attenuation structure, the method comprising providing an upper and lower layer together with one another, the upper layer including fluid storage recesses to collect and store fluid received from above the upper side thereof, and further comprising openings above the storage recesses to allow fluid communication between the upper side thereof and a lower side thereof such that overflow fluid from the storage recesses can drain through the openings; and the lower layer and including drainage pathways to collect and provide controlled drainage of fluid received from the upper layer;

5 wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, and the upper and lower layers are arranged such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower layer.

Amendments to the claims have been filed as follows

Claims:

08 06 18

1. A storage and attenuation structure for a drainage system, the structure comprising:

an upper layer for supporting material above an upper side of the upper layer, and 5 including fluid storage recesses to collect and store fluid received from above the upper side, and further comprising openings above the storage recesses to allow fluid communication between the upper side and a lower side of the upper layer such that overflow fluid from the storage recesses can drain through the openings; and a lower layer for receiving fluid drained from the upper layer, and including drainage

10 pathways to collect and drain fluid received from the upper layer, wherein the drainage pathways are formed between the projections in the lower layer;

wherein, the drainage pathways of the lower layer are in fluid communication with space between the fluid storage recesses in the upper layer, such that the space between the fluid storage recesses provides additional fluid storage capacity beyond the capacity of the lower

15 layer.

2. The storage and attenuation structure of claim 1, wherein the lower and upper layers both comprise sheet materials.

20 3. The storage and attenuation structure of claim 1 or 2, wherein a filter layer is provided between the upper layer and the lower layer.

4. The storage and attenuation structure of any preceding of claim, wherein the storage and attenuation structure comprises and is arranged with the outflow controller to control outflow

25 from the drainage pathways of the lower layer.

5. The storage and attenuation structure of claim 4, wherein the drainage pathways are arranged to channel fluid to the outflow controller to discharge the fluid at a controlled rate.

30 6. The storage and attenuation structure of any preceding claim, wherein the storage and attenuation structure operates to provide an air gap between fluid stored in the storage recesses and fluid draining from the lower layer, such that static pressure from fluid in the upper layer is not relevant to the rate of release of fluid from the storage and attenuation structure.

7. The storage and attenuation structure of any preceding claim, wherein one or more of the openings is at least partially surrounded by a border of material, the border of material being that which separates adjacent storage recesses.

08 06 18

8. The storage and attenuation structure of any preceding claim, further comprising a storage recess cover, provided as a fluid permeable material arranged in use to maintain growing medium and plant material away from the storage recesses and/or the openings.

5 9. A drainage system, comprising a green roof drainage system incorporating the storage and attenuation structure described in any one of claims 1 to 8.

10. A method of providing drainage using the storage and attenuation structure of any one of claims 1 to 8, the method comprising installing the storage and attenuation structure in a

10 structure to be drained.