The present disclosure generally relates to filtering sediment and debris from collecting in storm water drainage systems, and in one aspect, to temporary sediment retention assemblies, systems, etc., and methods for protecting openings of a storm water drain system and filtering or otherwise preventing sediment and debris from being washed and/or being deposited into the storm water drainage system, while still enabling water to pass into the inlet.
In the construction of residential and other types of developments, a road system generally is first marked out and the streets into and through the development are cut and graded. Thereafter, the storm water drainage system for the development is constructed, typically including underground drainage pipes, collection boxes and culverts, and inlets. The inlets generally can include cylindrical concrete pipes that are installed vertically, but can also include square or V-grate type inlets, and/or other types or configurations. The lower ends of the inlets connect to the collection boxes and the drainage pipes of the storm water drainage system, while their upper ends being substantially at or above street level, forming manholes or drain openings along the street.
Until a street has been substantially completed, drainage pipes and inlets must be kept substantially free of sediment and debris pursuant to various state and county building codes. Keeping sediment and debris out of the drainage system however can be very difficult to accomplish as during grading of the roads and curbs, as well as additional grading on site, sediment and debris typically is pushed to the sides of the street by motor graders, bulldozers, and thus may pass into the upper ends of the inlets. In addition, rain, runoff, wind, etc. also tend to wash or blow sediment and debris into the open ends of the inlets, which will then collect in the collection boxes and storm water drainage system.
Devices such as the Silt Saver frame & filter assembly have been developed to provide a system for temporarily protecting and preventing sediment and debris from enter the drainage pipes. And, such devices have been effective in preventing sediment and debris from entering drop inlets and other, similar drainage pipes. However, drainage inlets and other, similar devices needing protection can vary in size and shape, particularly as new uses and new drainage structures are developed, and it is important for filter assemblies or structures for filtering sediment for runoff water to be securely mountable to such newer and various existing inlet designs, so that sediment and debris can be substantially deposited or filtered from runoff water flows and to guard against collapse or shifting of the filter assembly during high winds or other weather conditions.
Accordingly, a need exists for adaptable sediment retention and filter assemblies that can filter or remove sediment, dirt, and debris from runoff water flows and prevent such materials being washed or blown into a storm water drainage system, and that addresses the foregoing and other problems in the art.
Briefly described, the present disclosure is, in one aspect, directed to methods and systems for providing a temporary and substantially rigid sediment retention assembly for protection of drainage openings or inlets of storm water drainage systems from ingress of sediment and debris.
In embodiments, a temporary sediment retention assembly can be configured for filtering water or other liquids entering an inlet or a range of varying size and/or configuration inlets or other openings of a variety of storm water drainage systems. The temporary sediment retention assembly generally can include a substantially rigid frame or body configured to seat over and substantially cover an inlet, or range of inlets, of a storm water drainage system(s), and a filter material assembly or cover that is adaptable to fit or be received over and substantially cover and/or enclose the rigid frame.
In some constructions, the substantially rigid frame or body can include a series of spaced, vertically extending slats, ribs, or other frame structures defining the frame, and a plurality of openings or passages defined therethrough to allow for the passage of water or other liquids through the frame and into the storm water drainage system. For example, the slats can be spaced from one another to define a series of spaced openings or passages that enable the flow of water through the sediment retention device while blocking passage of large debris, sediment and sediment. In additional or alternative constructions, the frame or body can include one or more substantially solid walls with openings defined therethrough or that is otherwise constructed with openings or passages to enable a substantial flow of water or other liquids therethrough.
The frame can include a first or upper portion (e.g., having a cylindrical shape, dome shape, etc.), and a base or second, lower portion formed with or connectable to the upper portion at or adjacent a lower end of the upper portion. The base can have varying constructions, shapes, or configurations, including, but not limited to, one or more round, square, rectangular, triangular, or polygonal shapes or other constructions, that can be selected or adapted to correspond to a particular size, shape, or configuration of an inlet or range of inlets with which the temporary sediment retention is to be used.
In some implementations, a temporary sediment retention assembly can include a plurality of different bases that are interchangeably connectable to the upper portion of the frame or body, such that the frame or body is adaptable to correspond to a range of differing size and/or constructions of inlets or other drainage structures.
The base (or bases) further can include one or more movable portions or adapters or that are configured to extend coverage of the temporary sediment retention assembly to overlap and cover additional areas and substantially eliminate gaps in coverage over the inlet through which sediment or debris can pass.
In some embodiments, the cover can include a cover material formed from a filter or screening material having one or more filter or screening sections, such as a sheet(s) of filtering material, and shaped, dimensioned, sized, or configured to correspond to, fit over, or otherwise be at least partially received over the frame and extend over at least a portion of the base. The cover further can be designed to be adaptable to various constructions, shapes, or configurations of bases. The cover material also can include a plurality of filtering or screening materials or have a plurality of filter material sections that form a multistage filter.
The cover can include at least one filter material or filter material section that has a plurality of openings with a first opening size that facilitates substantial sediment retention, e.g., for deposition and filtering sediment particles of sizes that meet or exceed federal, state and county regulations for storm water filtration and control; and further can include at least one filter material or filter material section having a plurality of openings with a second larger opening size that facilitates substantial water release therethrough, e.g., to define one or more release zones or stages along the temporary sediment retention assembly. However, the cover can include a single filter material that provides substantial sediment retention and adequate water release/passage without departing from the scope of the present disclosure.
With the cover fitted on or about the frame, each filter material (or material section) generally can extend for a prescribed amount in a substantially vertical direction along the frame and can extend horizontal direction, substantially around the periphery or circumference of the frame. In some aspects, the opening sizes of the filter material(s) or material section(s) can increase, decrease, or change based on their respective vertical positions along the frame. In some constructions, openings with larger opening sizes can be arranged generally above openings with smaller opening sizes, and in additional or alternative constructions, smaller sized openings can be arranged generally above larger sized openings.
The cover further can include a top cover portion that is configured to fit over and substantially cover the upper portion of the rigid frame; and a bottom cover portion that is designed or adaptable to be at least partially fitted over the base and other bases having a particular construction, shape, or configuration that are connectable to the rigid frame (or connectable to or formed with other rigid frames).
The temporary sediment retention assembly also can include a plurality of retention sections or portions formed with or connectable to the cover and configured to help to substantially secure the cover to the frame or body and/or to help to substantially secure the rigid frame in place over the inlet of the storm water drainage system. For example, the retention portions can include receptacles, such as pouches, pockets, etc., which can be coupled to or formed with the bottom portion of the cover and configured to receive a ballast, such as rocks, weights, or other weighted materials, to help to substantially secure the cover or rigid frame.
Various objects, features and advantages of the present invention will become apparent to those skilled in the art upon a review of the following detail description, when taken in conjunction with the accompanying drawings.
It will be appreciated that for simplicity and clarity of illustration, elements illustrated in the Figures are not necessarily drawn to scale. For example, the dimensions of some elements may be exaggerated relative to other elements. Embodiments incorporating teachings of the present disclosure are shown and described with respect to the drawings herein, in which:
The use of the same reference symbols in different drawings indicates similar or identical items.
The following description, taken in combination with the Figures is provided to assist in understanding the teachings disclosed herein. The description is focused on specific implementations and embodiments of the teachings, and is provided to assist in describing the teachings. This focus should not be interpreted as a limitation on the scope or applicability of the teachings.
Referring now to the drawings in which like reference numerals indicate like parts throughout the several views,
As indicated in
It further will be understood that the dimensions of slats 22 and/or openings 24 may be varied in accordance with the needs of the users of the temporary sediment retention assembly 10 to provide larger or smaller passages. For example, larger passages having various configurations, such as rectangular, triangular, etc. can be used to provide larger open areas, such as at the upper or lower ends of the passages as needed. The rigid frame or body 20 typically can be molded, extruded or otherwise formed from a durable plastic material such as in the polyvinylchloride (“PVC”), acrylonitrile-butadiene-styrene (“ABS”), high density polyethylene (“HDPE”), high molecular weight polyethylene (“HMWPE”), or acetyl resin such as “DELRIN”, or any other similar rigid, durable, high strength materials, including wood or metals such as aluminum, that are relatively lightweight for ease of handling.
As
In some embodiments, as indicated in
The base or bases 32 are not limited to the constructions shown in
In addition,
In some embodiments, the cover material 102 includes a plurality or assembly of sections of filter materials 104 that are selectively formed or connectable together, such that the cover 100 is designed or adaptable to correspond to one or more portions or components of a rigid frame 20 having a particular construction, configuration, etc., or to a range of rigid frame 20 constructions, configurations, etc. For example, one or more of the sections of filter materials 104 of the plurality or assembly thereof can be specifically tailored for a particular base 32 construction and/or can be expandable, retractable, or otherwise reconfigurable to correspond to a range of base 32 constructions, configurations, etc. The sections of filter materials 104 further can be selected to have different or substantially the same sized openings.
In additional or alternative embodiments, the cover material 102 can include a single substantially uniform material, e.g., that is continuous from a bottom end portion 100A to a top end portion 100B of the cover 10, and which can be configured to have various areas designed or adaptable to correspond to various portions or components of a rigid frame, e.g., at least one area corresponding to a particular base 32 construction and/or can that is expandable, retractable, or otherwise reconfigurable to correspond to a range of base 32 constructions, configurations, etc. . . .
As generally shown in
The sediment retention stage 110 can include one or more filter materials or filter material sections 114 that include openings 106 with opening sizes less than or equal to 30 seize mesh or less than or equal to about 600 μm, such as opening sizes ranging from about 30 sieve mesh (about 600 μm) to about 80 sieve mesh (about 180 μm) or less. Greater or lesser apparent opening sizes also can be used to provide for increased capture of sediment, depending upon the environmental conditions of the site at which the temporary sediment retention assembly is to be used, e.g., the filter material sections 114 can have an opening sizes less than about 100 sieve mesh or less than about 150 μm.
As indicated in
Typically, as indicated in
In some implementations, the plurality of filter material sections or filter materials 104 are substantially permanently secured together, e.g., sewn together, fused together, etc., to form the cover material 102, and in other implementations, the filter material sections 104 can be releasably coupled (e.g., by one or more releasable connectors or fastening assemblies, such as button assemblies, hook and loop, zippers, etc. or other suitable releasable connectors or fastener assemblies) to one another to allow for exchanging or rearrangement of the various filter material sections 104, e.g., to reconfigure the multi-stage filter, to reconfigured the cover 100 to corresponds to a certain base construction or configuration or range of base constructions or configurations.
In some embodiments, at least part of the top cover portion or upper portion 120 can be dyed or painted with a fluorescent color, such as a bright green, orange, red, etc. This will make the cover 100 and thus the sediment retention assembly itself stand out more prominently and provide a clear and easy to recognize visual indicator of the existence and position of the drop inlet for workers.
In addition, as generally indicated in
In one embodiment, the bottom cover portion 122 will be specifically tailored, designed shaped, dimensioned, etc. or otherwise configured to be substantially fitted or received over a certain base 32, i.e., a particular base 32 having a specific construction, configuration, etc., such as round, square, rectangular, etc., base; a base including one or more adapters; etc. In other embodiments, however, the bottom cover portion 122 will be expandable or contractible or otherwise reconfigurable or adaptable such that the bottom cover portion 122 can sufficiently cover, or otherwise be substantially fitted or received over, a range of bases 32 having various different constructions, configurations, etc., with the bottom cover portion 122 of the cover material 102 being sufficiently taut or otherwise under tension.
In one example construction, the bottom cover portion 122 can include one or more sufficiently elastic portions or sections, such as elastic or clinching materials including elastic bands, strands, fibers, yarns etc., and/or other suitable elastic material or clenching materials elastic adapted to enclose the bottom cover portion 122 (e.g., an outer, lower edge thereof) about the base 32. The one or more elastic portions, or materials, can be stretchable or expandable to allow the bottom cover portion 122 to be expanded or stretched out to be fitted or otherwise at least partially received over one or more specifically constructed, configured, etc., bases 32, and also can retract or bias the bottom cover portion 122 towards a retracted or minimized configuration to allow the bottom cover portion 122 to be additionally fitted or at least partially received over one or more differently constructed, configured, etc., bases 32, e.g., with a sufficient tautness or tension.
In other constructions, the bottom cover portion 122 can include one or more sections or areas that are selectively foldable, tuckable, rollable, etc., such that the bottom cover portion 122 is retractable to be fitted or otherwise at least partially received over one or more specifically constructed, configured, etc., bases 32, with sufficient tautness or tension, and that also are un-foldable, untuckable, unrollable, etc., or that can be otherwise unfurled or expanded to be additionally fitted or at least partially received over one or more differently constructed, configured, etc., bases 32.
In even further additional or alternative constructions, the bottom cover portion 122 can include one or more drawstring assemblies, winch assemblies, mechanical fasteners, etc., or other suitable assemblies or mechanisms that are expandable and contractible to allow the bottom cover portion 122 to be fitted or otherwise received over specifically constructed, configured, etc. bases 32 or a range thereof, while maintaining sufficient tautness or tension.
The cover material 102 also can include additional cover portions made up of or otherwise including one or more filter materials 104 that can be used in place of or in conjunction with the top and/or bottom cover portions 120/122, which additional portions can be selectively designed, constructed, or configured and/or reconfigurable or adaptable to correspond to one or more portions of the upper frame portion 30 or base 32.
In additional or alternative constructions, the top 120 and bottom 122 cover portions (and/or additional cover portions) can be substantially permanently affixed to one another. More specifically, the top 120 and bottom 122 portions (and/or additional portions) can be fixed together at a one or more joints or seams 126 (
In one embodiment, shown in
As
In addition, the cover material 102 can include one or more reinforcing portions, elements, etc. that are configured to reinforce or strengthen the connections between the filter material sections 104 and/or otherwise reinforce or strengthen the cover material 102 (or filter materials 104). The reinforcing portions generally can include various resilient reinforcing materials applied to or formed with the filter materials 104. For example, the reinforcing portions can include areas of increased thickness, increased weaves, etc., of fibers of the filter materials 104, such as areas of increased denier per fiber, and/or other bands, strips, patches, etc. of material, or other reinforcing portion, elements, etc. that provide load support strength, e.g., as hydrostatic pressure is increased against the temporary silt retention assembly 10, such as due to rising storm water flow. The reinforcing portions can be attached to or integrated within the cover material 102 or individual filter materials by weaving, stitching, bonding, such as through the use of adhesives, thermal bonding, or the like, needle punching or other, similar applications, and/or can be attached with fasteners such as staples, hog rings, etc. . . .
The foregoing description generally illustrates and describes various embodiments of this disclosure. It will, however, be understood by those skilled in the art that various changes and modifications can be made to the above-discussed constructions and systems without departing from the spirit and scope of this disclosure as disclosed herein, and that it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as being illustrative, and not to be taken in a limiting sense. Furthermore, the scope of the present disclosure shall be construed to cover various modifications, combinations, additions, alterations, etc., above and to the above-described embodiments, which shall be considered to be within the scope of this disclosure. Accordingly, various features and characteristics as discussed herein may be selectively interchanged and applied to other illustrated and non-illustrated embodiment, and numerous variations, modifications, and additions further can be made thereto without departing from the spirit and scope of the present invention as set forth in the appended claims.
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