The rain and storm water filtration systems discussed herein relate to filtration systems that employ screens to filter debris and other unwanted material from water streams and, more specifically, to filtration systems having a screen comprising a plurality of wedge wires or tilted wedge wires for filtering water streams.
Rainwater downspouts, curbside storm water runoff collectors, and similar water conduits share a common purpose: removal of water from where it is undesired, be it the roof of a building, a city street, a storm basin, or the like. All such conduits allow a volume of water to pass therethrough. Leaf litter, sand, dirt, grit, and other debris can accumulate within such conduits and clog them, rendering them ineffective. Equally bad, the poor design of many water conduits allows debris to pass through to downstream channels and, ultimately, the ocean, with a consequent negative environmental impact.
Not surprisingly, much effort and money has been spent devising ways to avoid clogged water conduits and contaminated water streams. Patents have been granted for inventions designed to filter water at curbside storm drains (U.S. Pat. No. 6,231,758 to Morris et al.), to treat water in a horizontal passageway (U.S. Pat. No. 6,190,545 to Williamson), to create temporary stream filtration systems (U.S. Pat. No. 4,297,219 to Kirk et al.), to remove downspout debris (U.S. Pat. No. 5,985,158 to Tiderington), and to shield rain gutters on the eaves of a building (U.S. Pat. No. 4,435,925 to Jefferys).
However, with respect to downspouts and storm water systems, the prior art has several shortcomings. Among other things, it is difficult to devise a system that both operates under high flow and effectively filters out small particulate matter and other debris. This is because a filter element that accommodates large flow must also be designed with large spacing to suit the large flow. However, large spacing allows medium to small particulates and waste to pass through unfiltered. Conversely, a filter element designed to trap small particulate matter typically obstructs flow. An ideal water runoff filter would be both capable of passing high flow therethrough and removing small waste and debris.
Accordingly, there remains a need for a filter system for removing debris from a water stream using a filter element that is amenable to high volume flow, capable of removing or trapping waste the size of or even smaller than the size of the gap used for the filter and, preferably, self-cleaning.
The present invention integrates a Coanda screen (sometimes called “Coanda-effect” screen) into water collection systems such as downspouts, storm runoff collectors, sewer drains, and similar conduits and receptacles. An exemplary embodiment includes retrofitting an existing downspout section (or customizing a new downspout section) with a Coanda screen to provide a downspout with a highly efficient filter for removing debris from a stream of water. Depending on the water flow rate and the size of the debris encountered, different screen sizes and different screen mounting angles may be selected to accommodate the same. Filtered water can pass through the screen, while debris is retained by the Coanda screen and then collected in an optional retaining basket.
In another embodiment, a curbside inlet to a storm drain is fitted with a Coanda screen. The screen is mounted between a raw inlet basin and an outlet basin. Filtered water is allowed to pass over the screen and then fall through the screen into the outlet basin, which then flows onward via an outlet pipe. Captured debris and waste are allowed to fall into a retention basin. To remove waste and debris more effectively, a retaining basket is used. When full, the basket can be lifted out of the curbside inlet and emptied.
In yet another embodiment, there is provided a downspout filter assembly comprising a housing comprising an inlet, and outlet, an interior cavity, and an entrance to the interior cavity; a filter comprising a plurality of wedge wires mounted in the interior cavity of the housing having a portion positioned directly subjacent the inlet; and at least one media pad positioned under the filter for scrubbing water before it exits the outlet.
The present invention may also be practice by providing a downspout filter assembly comprising a housing comprising an inlet, and outlet, an interior cavity, and at least one surface positioned along a first plane; a Coanda filter positioned inside the interior cavity at an angle to the first plane; one or more media pads positioned in the interior cavity at a position below the Coanda filter.
In still yet another aspect of the present invention, there is provided a downspout filter assembly comprising a housing comprising an inlet, an outlet, and an interior cavity; a pair of rails attached to two sections of the interior cavity; at least one removable container positioned on the pair of rails; a media pad positioned in the at least one removable container or below the at least one removable container; and a filter comprising a plurality of wedge wires mounted in the interior cavity in a position above the media pad.
Yet in another aspect of the present invention, there is provided a downspout filter assembly comprising a housing comprising an inlet, and outlet, an interior cavity, and an entrance to the interior cavity; a filter comprising a plurality of wedge wires mounted in the interior cavity of the housing having a portion positioned subjacent the inlet; and at least one media pad positioned subjacent the filter for scrubbing water before it exits the outlet.
The present invention may also be practiced by incorporating a downspout filter assembly comprising a housing comprising an inlet, and outlet, an interior cavity, and at least one surface positioned along a first plane; a Coanda filter positioned inside the interior cavity at an angle to the first plane; at least one media pad positioned in the interior cavity at a position below the Coanda filter.
Yet, it is also within the spirit and scope of the present invention to incorporate a downspout filter assembly comprising a housing comprising an inlet, an outlet, and an interior cavity; a pair of rails attached to two sections of the interior cavity; at least one removable container positioned on the pair of rails; a media pad positioned in the at least one removable container or below the at least one removable container; and a filter comprising a plurality of wedge wires mounted in the interior cavity in a position above the media pad.
These and other features of the invention will be better understood when considered in conjunction with the accompanying drawings, wherein like part numbers denote like or similar elements and features, and wherein:
In accordance with the present invention, a highly effective filter system for a rain water downspout, sewer inlet, curbside storm water drain, or similar water runoff conduit or receptacle is provided. A preferred embodiment of an improved downspout 10 is shown in
An existing downspout can be upgraded or retrofitted by cutting out or otherwise removing a portion thereof, and installing an upgraded downspout portion or section 40 therein, using a slip joint, welds, adhesives, mechanical fasteners, or other conventional attachment means. Alternatively, an entire downspout can be fabricated as such and installed as part of a rain water removal system that includes one or more gutters and mounting hardware. In either case, the improved downspout provides a path for funneling water from a roof (or a deck, mezzanine, or other surface) to grade (e.g., street level) or to a storm water runoff drain or a main sewer line. Effluent from the downspout eventually flows to a storm drain or sewer system and then to the ocean, in some cases via a water treatment facility.
The downspout 10 is preferably constructed of stainless steel, galvanized steel, aluminum, plastic, or some other durable and water-resistant material, and has an interior and an exterior, and a cross-sectional shape that is generally rectangular. Alternatively, the downspout can have a generally circular cross-section or other desired geometry. In an exemplary embodiment, the downspout 10 is physically attached to an exterior wall 12 of a house or a building by any conventional means, such as downspout bands (not shown) anchored to the exterior wall. Water falling into the downspout passes into the upgraded downspout section 40 to the Coanda screen 20. The Coanda screen 20 allows water to pass through, but traps waste and debris behind.
A Coanda screen acts by a shearing action referred to as the “Coanda effect,” which is discussed below in greater detail. In
The Coanda screen 20 is mounted at an angle within the upgraded downspout portion 40, with the upstream end 26 of the screen elevated relative to the downstream end 28 of the screen. As shown in
To ensure that a substantial portion of the water entering the downspout is filtered, it is preferred that the screen have a large enough area to make contact with all four walls 46-49 of the interior of the downspout housing. Alternatively (or, in addition), one or more baffles are mounted within the downspout to divert the flow of water toward the screen. In
In
The downspout opening 60 provides access to the Coanda screen for maintenance and cleaning. Although the screen is self-cleaning, occasionally debris may become trapped within the downspout or (rarely) wedged between the wires 30 that form the screen. Access to the screen is facilitated by providing the downspout opening 60 with appropriate dimensions relative to the screen 20. A preferred downspout opening 60 has a width approximately 50-100% of the interior width of the downspout, and a height approximately 33-75% of the vertical profile of the screen 20, the latter being measured at the wall opposite the downspout opening (the back wall 47 in
A retaining basket 80 to catch debris caught by the Coanda screen is mounted to the downspout just below a debris deflector plate (further discussed below), using conventional means, such as welding, adhesives, mechanical fasteners, and the like. In an exemplary embodiment, the retaining basket 80 comprises a tightly woven screen made of steel, aluminum, or other weather-resistant material. Debris that does not freely fall into the retaining basket 80 (i.e., debris that clings to the filter due to friction) is eventually pushed out the downspout opening 60 by additional water flowing from the gutter. Water clinging to debris caught in the retaining basket 80 can drip onto the splash guard 100 by passing through the holes of the retaining basket 80. Alternatively, if an underground header is used to connect with the downspout, water that passes through the retaining basket can be caught by a collector (not shown) mounted beneath the retaining basket, and channeled to the header.
In an exemplary embodiment, the downspout is also equipped with an external debris deflector plate 110. The debris deflector plate is mounted just below the downspout opening 60 along the external surface of the front wall 46, just above the retaining basket 80. The debris deflector plate covers any space between the downspout 10 and the retaining basket 80, and ensures that debris exiting the downspout opening does not fall between the downspout and the retaining basket.
In an exemplary embodiment shown in
Reference is now made to
Similarly,
Coanda screens are available from a number of manufacturers and retailers, including Hydroscreen, LLC of Denver, Colo., and Johnson Screens of New Brighton, Minn. The screen is described in an article entitled “Hydraulic Performance of Coanda-Effect Screens” by Tony Wahl for publication in the Journal of Hydraulic Engineering, Vol. 127, No. 6, June 2001, the entire contents of which are expressly incorporated herein by reference as if set forth in full.
As explained by Wahl, the Coanda effect is a tendency of a fluid jet to remain attached to a solid flow boundary. As shown in
This phenomenon is used to great effect in the present invention. Debris-laden water is effectively filtered at the Coanda screen. Any debris that does not fall into the retaining basket 80 during rainfall eventually dries on the screen, and either falls into the basket later, or can be manually removed via the downspout opening 60.
In an alternate embodiment of the invention shown in
In an exemplary embodiment, the Coanda screen 20 is mounted between a first weir 230 and a second weir 240. The screen has a concave surface, with a radius of from about 6 inches to infinity, and is outfitted with an acceleration plate 250. The acceleration plate 250 is a metal plate of hardened steel, such as stainless steel and the like, mounted to the upstream end 26 of the screen.
The acceleration plate has a width of approximately 2 inches or higher depending on the size of the storm drain system. When water flows from the raw inlet basin 210 over the weir 230, it has a relatively low flow velocity. If water is allowed to flow over the screen 20 without first having the necessary flow velocity, the screen's ability to filter out debris will greatly decrease. The acceleration plate provides a vertical drop of about 2 inches or higher, allowing in-coming water to build up velocity before it contacts the first wedge wire on the screen.
Debris caught by the Coanda screen can slide into a retention basket 260 located within a retention basin 262. In an exemplary embodiment, the retention basket 260 is equipped with a handle 264, which allows the retaining basket to be lifted out of the basin, whereupon the debris can be discarded. The basket 260 may be a conventional basket and may be constructed out of medium to large steel wire mesh. Due to its size, it may be necessary to lift the basket with a crane or a flit truck having a lift.
In an alternate embodiment of the upgraded downspout 10 shown in
In another alternate embodiment of the upgraded downspout 10, shown in
Referring now to
In one exemplary embodiment, the filter components comprise a Coanda filter 20, a collection container or a debris container 292, an outlet container 294, and a filter medium 296, which may comprise one or more media pads 298a, 298b for one or more different filtering functions. Alternatively, a filter comprising a plurality of wedge wires may be used to filter debris and other contaminants, with tilted wedge wires or Coanda screen being more preferred. Screen with wedge wires are commercially available, for example, through Goel Engineers in India, which has the following website: http://www.goelka.com/wws.htm. The filter components are housed inside the interior cavity 288 of the housing 282 and are closed therein by a door cover 290 abutting the housing flange 300 and a latch 302, which may embody a key lock or other prior art means for securing the door to the flange. In one exemplary embodiment, the door cover 290 may comprise two or more door sections and may include a gasket 304 for providing a relatively tight seal as compared to when no gasket is used. The gasket may include any prior art gaskets and may adhere to the door cover by adhesive. The door cover 290 is connected to the housing 282 via one or more conventional hinges or fasteners. For venting, one or more vent holes 291 may be incorporated on one or more sides of the housing 282. If the vent holes 291 are incorporated, they are preferably positioned at a location with minimal water splash.
The housing 282 may comprise a number of different shaped configuration, such as a rectangular shaped box, a square shaped box, or a cylindrical shaped box, with a rectangular shaped box being more preferred. The housing 282 may be made from a number of metallic sheets, such as stainless steel sheets, tin sheets, sheet metal, and zinc coated sheet metal with stainless steel sheets being more preferred. Alternatively, plastic, fiberglass, or synthetic plastic materials may be used.
Referring to the referenced length L, height H, and width W of the housing 282, in a preferred embodiment, the filter assembly 280 is mounted along a lengthwise direction L against a structure 348 (
Also shown in
Broadly speaking regarding operation of the downspout filter assembly 280, during a rain storm or cleaning operation in which water is used, water is directed down a downspout, flows through the downspout inlet 284, is filtered by the Coanda filter 20, in which solids and other suspended contaminants are filtered by the filter 20 and are trapped along the upper surface of the filter and the passes through to the outlet container 294. The trapped solids and other suspended contaminants are subsequently collected in the collection container 292, either by being pushed into the container 292 by later trapped solids, gravity, or by a service technician. The filtered water that passes through the filter 20 is additionally filtered by the filter medium 296 positioned in the outlet container 294 and by the final filter media 308 located in the sump 310, if incorporated. Water then flows out the filter assembly 280 via the downspout outlet 286.
Referring now to
The containers 292, 294 incorporated herein may be made of a metallic mesh material for durability, such as a stainless steel mesh material. However, rubber or hard plastic containers may also be incorporated where desired. In one exemplary embodiment, the mesh size for the collection container 292 should be smaller than the mesh size for the outlet container 294 to prevent or minimize small solids collected in the collection container 292 from escaping through the plurality of openings provided by the mesh. Obviously, the mesh size for both containers can be similarly sized for ease of manufacturability. Handles 322 may be added to the containers 292, 294 for ease of handling the containers during cleaning or other maintenance operation when the containers are removed from the interior cavity 288.
The outlet container 294 and the media pads 298a, 298b should be sized such that the perimeter of the pads contact the interior surface of the outlet container 294 when the media pads 298a, 298b are placed therein (
In one exemplary embodiment, an exit flow deflector 324 comprising a base 326 and two side walls 328 each comprising a rail or a flange 330 are incorporated in the filter assembly 280. The base 326 preferably has a surface that is sloped about 10-30 degrees from the surface of the flanges 330 for directing flow entering the sump area 310, as further discussed below. The flow deflector 324 should have a length and a width approximately that of the outlet container 294. The flow deflector 324 is preferably made from a rigid material, such as a sufficiently gauged metallic sheet or a hard plastic.
In an exemplary embodiment, a main baffle or deflector plate 332 may be incorporated in the filter assembly 280. As further discussed below, the main baffle 332, if desired, may be installed subjacent or behind the filter 20 so that as water passes through the filter 20, it is deflected away from the back side wall 334 of the housing 282 by the main baffle. As readily apparent, this arrangement allows the baffle to direct water away from the housing wall so that the water can then flow through the outlet container 294 where it could be scrubbed or cleaned by the media pads 298a, 298b. When installed, the surface of the main baffle 332 should be angled about 5-30 degrees relative to the back sidewall 334. Rivets, spot welding, brackets, fasteners, or other conventional attachment means may be used to attach the flange section 336 of the main baffle 332 to the back sidewall 334.
Two brackets or rails 338, one on an outside sidewall 340 and one on an inside sidewall 342, are incorporated for placement of the exit flow deflector 324 and the two containers 292, 294 thereon. The rails 338, which resemble right-angle brackets, provide two ledges that protrude from the two sidewalls 340, 342. The ledges are configured to support the deflector 324 and the two containers 292, 294 when the same are placed thereon. More particularly, the rails 338 support the deflector 324 and the two containers 292, 294 by first placing the two flanges 330 of the deflector 324 on the rails 338 and then placing the containers 292, 294 over the rails, with the outlet container 294 preferably placed directly over the deflector 324 (See, e.g.,
A containment dam 342 is positioned at the entrance 344 to the interior cavity 288 of the housing 282. The containment dam 342 preferably contacts and forms a seal with the two side walls 340, 342 and the base wall 346 of the housing. The containment dam 342 preferably extends about ⅕ to about ⅓ of the height of the entrance 344, and should at least be level with or rises above the surface of the rails 338. The containment dam 342 may be attached to the housing using any prior art methods, including forming the dam by bending a portion of one or more of the sidewalls and then using welding or epoxy to seal the seam.
Referring now to
As shown, when water 360 enters the downspout assembly 280 via the inlet 284 and into the interior cavity 288, the water makes contact with the filter 20. As previously discussed, debris and other solids carried by the water 360 are then trapped by the filter 20 along the upper surface 22 of the filter. The solids and the debris are then pushed by the stream of incoming water and incoming solids, and/or by gravity, and fall into the collection container 292. Water, however, passes through the filter 20 to the underside 24 of the filter in the direction of the main deflector plate 332. During normal flow, water flows in a downward direction towards the outlet container 294, where it is then cleaned or scrubbed by the media pads 298a, 298b before being deflected again by the exit flow deflector 324. The exit flow deflector 324 channels the water over the final filter media 308 where it is further cleaned or scrubbed before existing the housing 292 via the outlet 286.
As readily apparent, the media pads 298a, 298b, 308 may be eliminated, replaced with other media pads, or used in combination with additional media pads depending on the desired outcome and/or on environmental regulations. When media pads are used, treatment pad separators 362 may be used to separate the media pad from an adjacent pad or from a solid surface, such as the bottom of the housing. The separators 362 may be made from nylon or plastic webbing sheets such as spun-bonded webbing sheets, steel mesh, porous media, or other material to provide gaps or passages for the water flow.
In an exemplary embodiment, a passage 364 is provided internally of the interior cavity 288 for bypassing water 360 around the media pads 298a, 298 positioned inside the outlet container 294. This passage 364 is located intermediate the lower edge of the main deflector 332 and the top of the outlet container 294 proximate the back sidewall 334 of the housing 292. In the event the media pads 298a, 298b are clogged and water backs up in the outlet container 294, water can escape through the passage 364 to then flow out of the housing 292 via the outlet 286.
Although the invention has been described with reference to preferred and exemplary embodiments, various modifications can be made without departing from the scope of the invention, and all such changes and modifications are intended to be encompassed by the appended claims. For example, an upgraded downspout section can be manufactured as a separate unit and installed as a new downspout. Other materials than those described herein can be used to make the various components of the apparatus described. Changes to the way the baffles are installed, the way they are shaped, the way the deflector plates are installed, and the way the screens are installed within the housing can be made. Other alterations and modifications may be made by those having ordinary skill in the art, without deviating from the true scope of the invention.
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