This invention relates to collection and storage of storm water. More particularly, it relates to subsurface water storage structures and methods of making same.
Raw undeveloped land is generally porous, allowing direct infiltration of rainfall. Such infiltration recharges subsurface water-bearing strata and generally limits run-off flooding while filtering out some pollutants. Development of land for commercial or residential purposes, however, significantly impairs natural infiltration. Where the surface is covered with permanent or semi-permanent structures such as roads, walkways, parking lots, structures with roofs and the like, natural infiltration is blocked or substantially impaired.
Interference with surface infiltration results in rapid and excessive run-off water which causes flooding and pollution of surface water resources. Accordingly, national, regional and local regulatory agencies now often require all or part of rainfall run-off (conventionally referred to as storm water) to be managed onsite.
Traditionally, storm sewers and the like have been used to conduct storm water to run-off channels or the storm water is collected in detention basins or ponds. Such open storage facilities, however, not only occupy valuable real estate, they create safety hazards and tend to attract unwanted insects and other creatures as well as causing odor problems and weed growth. To minimize these hazards, subsurface storage facilities have been developed where excess run-off can be temporarily stored until it percolates into adjacent earth or is removed for other uses.
Most conventional subsurface storage facilities comprise layers of gravel and/or crushed rock contained in a pit or the like in which the water may be collected and gradually removed by drainage, seepage and the like. Unfortunately, the water retention capacity of such systems is severely limited by the volume occupied by the crushed rock, etc. More recently, storage systems have been developed which employ a matrix or grid of interlocking support structures such as disclosed in U.S. Pat. No. 6,095,718 disposed in an enclosed cell structure. Such support structures occupy less space than crushed rock and the like and thus permit greater water retention capacity in smaller spaces but are often structurally unstable and are relatively expensive to manufacture and install, thus limiting their practical utility.
In accordance with the present invention, an assembly is provided which may be used as the support matrix or core in subsurface water retention systems which employ water retention cells or envelopes. In its simplest form the assembly comprises a plurality of hollow frustum-shaped bodies arranged in a supporting matrix with the ends of the frustum-shaped bodies aligned in parallel planes so that multiple assemblies may be stacked in alternating inverted layers with the ends of the frustum-shaped bodies connected to provide structural support columns. With the assemblies stacked in alternately inverted layers, the larger ends of the frustum-shaped bodies in one layer are connected to the larger ends of the frustum-shaped bodies in an adjacent layer and the smaller ends of the frustum-shaped bodies in one layer are connected to the smaller ends of the frustum-shaped bodies in an adjacent layer, resulting in a core matrix which, when positioned within a storm water retention cell, provides an extremely strong and rigid core structure. The assembly may be constructed of inexpensive materials and arranged to occupy less than three percent (3%) of the fluid volume of the water retention cell. Since the hollow bodies are frustum-shaped, the assemblies may be compactly nested and stacked for shipment but easily and readily arranged in alternately inverted layers onsite without special assembly tools or the like. The alternately inverted and interconnected frustum-shaped bodies provide extremely high compressive strength columns so that the core matrix provides a high strength rigid base for supporting heavy overburden without substantially reducing the fluid retention capacity of the subterranean cell and without the necessity of providing excessively strengthened cell wall and top structures. Other features and advantages will become more readily understood from the following detailed description taken in connection with the appended claims and attached drawing in which:
The above-described drawing is incorporated into and forms part of the specification to illustrate an exemplary embodiment of the invention. Throughout the drawing like reference numerals designate corresponding elements. The figures are not to scale but are intended to disclose the inventive concepts by illustration. This drawing, together with the description herein, serves to explain the principles of the invention and is only for the purpose of illustrating preferred and alternative examples of how the invention can be made and used.
It will be recognized that the principles of the invention may be utilized and embodied in many and various forms. In order to demonstrate these principles, the invention is described herein by reference to specific preferred embodiments. The invention, however, is not limited to the forms illustrated and described. Furthermore, the invention is not limited to use in connection with any particular size or shape of water retention cell or arrangement of storm water collection and distribution system but may find utility in various other applications involving collection and subterranean storage of water.
For purposes of this disclosure the terms “cell,” “pit,” “envelope” and the like are used interchangeably to mean any subterranean void in which storm water may be collected. Likewise, “assembly” is used herein in its broadest sense to denote a collection of interconnected bodies which may be arranged to form a structural supporting core for a storm water retention cell.
Storm water management systems, regardless of the means for collection and ultimate disposition of the collected water, require facilities for temporary retention of large quantities of water. Open pits and the like which collect surface run-off, along with other disadvantages, generally occupy too much valuable surface area and thus are increasingly being replaced by underground retention cells.
Subterranean water retention cells may be either enclosed containers (in which water is collected and stored for later disposition) or porous structures which permit ingress and/or egress of water through porous walls, floors, roofs and the like. Regardless of the type of retention cell, the cell structure must be sufficiently sturdy to support the overburden under which the retention cell is buried. Where the cell volume is relatively large and the overburden (such as a large structure, roadway for heavy vehicles, etc.) is substantial, the water retention cell must be designed to support the anticipated load.
A typical enclosed water retention cell 10, as illustrated in
Since the cell 10 is to be located underground, the structure must be sufficiently sturdy to support the anticipated overburden 16. However, construction costs must be minimized without substantially decreasing the fluid volume of the cell 10.
Typically, the floor 11, top 12 and side walls 13 are formed of flexible material such as plastic or the like and form an envelope supported by an internal core structure 100 and the surrounding earth 101. The core structure 100, however, must be sufficiently sturdy to support the overburden; must be inexpensive and easy to assemble; must be resistant to decay and deterioration; and must not substantially reduce the fluid capacity of the cell 10.
In the embodiment illustrated, the support structure 31 is sheet or panel extending parallel with and connecting the larger ends 32. It will be realized, however, that support structure 31 may take various other forms and be disposed at other positions relative to the frustum-shaped bodies. The functions of support structure 31 are primarily to maintain the spacing between and arrangement of bodies 30 and to provide lateral stability of the core structure 100 as discussed hereafter.
To form a core structure 100 such as illustrated in
In the preferred embodiment illustrated, axial alignment of the bodies 30 forming each vertical column is assured by connector means which join the mating ends of each pair of frustum-shaped bodies. As more clearly illustrated in
It will be understood that other connector means may be employed to join the mating ends of the frustum-shaped bodies. For example, the grooves 35, tongues 36, holes 37, bosses 38 and/or floors 39 may be provided with ridges, clamps, hooks, holes, ratchets or the like which interconnect the bodies 30 to form rigid columns. If desired, the mating ends of the bodies 30 may be secured together with glue or the like.
The assembly 20 may be formed of any suitable material by any suitable means which provides the necessary structural strength and minimum solid volume. In the preferred embodiment, the assembly 20 is formed by continuous thermal forming or injection molding of plastic materials such as polyethylene, polypropylene, PVC, HIPS or the like. Depending on the materials used, the design configuration and the load-bearing capacity required, the material thickness of the components of the assembly should be as thin as possible to minimize solid volume and thus maximize fluid volume of a water retention cell utilizing a core structure 100 comprised of alternately inverted assemblies 20.
In the preferred embodiment, each assembly is formed in a 10×9 array of frustum-shaped bodies 30 arranged on 76.2 mm centers. Each body 30 is 60 mm deep. The diameter of the larger end is 51.8 mm and the diameter of the smaller end is 36 mm, resulting in a frustum-shaped body 30 in which the inclination of the side walls 34 is 10° from vertical. Since the side walls of the frustum-shaped body are inclined with respect vertical, the vertical load-bearing capacity of a column comprised of such bodies greatly exceeds the vertical load-bearing capacity of hollow cylindrical columns having the same wall thickness. Furthermore, the structural rigidity of a core structure formed of assemblies 20 is described herein far exceeds the structural rigidity of a core structure of equivalent solid volume formed of cylindrical tubes or the like.
In the embodiment illustrated in
It will be appreciated that a plurality of assemblies 20 of identical structure may be positioned onsite to form core matrix for a water retention cell 10 of any desired dimensions. Since the ends of the bodies 30 in each alternating inverted layer are adapted to be interconnected simply by proper relational placement, the entire core may be assembled without special tools or assembly techniques. When the core structure is assembled as illustrated in
Where the core structure 100 is employed in a closed cell as illustrated in
In the embodiment illustrated in
It will be appreciated that a plurality of assemblies 20 of identical structure may be positioned onsite to form core matrix for a water retention cell 10 of any desired dimensions. Since the ends of the bodies 30 in each alternating inverted layer are adapted to be interconnected simply by proper relational placement, the entire core may be assembled without special tools or assembly techniques. When the core structure is assembled as illustrated in
Where the core structure 100 is employed in a closed cell as illustrated in
It will be further appreciated that the alternately inverted frustum-shaped bodies of the invention need not be provided in assemblies 20 of limited size. The product may be formed in large sheets or in continuous lengths which are rolled for trans-shipment and cut to desired length onsite. However, with the frustum-shaped bodies 30 formed in assemblies 20 and interconnected by support structure 31 attached at the larger ends 32 thereof, the assemblies 20 may be arranged in nested stacks for shipment and storage.
It will be apparent from the foregoing that the principles of the invention may be used to form core structural assemblies for a wide variety of water retention cells. The shape and size of the assembly, as well as the materials of construction and arrangement of components, may be varied as desired to accommodate a wide variety of applications.
It is to be understood that even though numerous characteristics and advantages of the invention have been set forth in the foregoing description together with details of the structure and function of the invention, this disclosure is to be considered illustrative only. Various changes and modifications may be made in detail, especially in matters of shape, size, arrangement and combination of parts, without departing from the spirit and scope of the invention as defined by the appended claims.