The present disclosure relates generally to stormwater management and particularly to chambers for retaining and detaining water beneath the surface of the earth.
Generally speaking, stormwater management systems are used to accommodate stormwater underground. Depending on the application, stormwater management systems may include pipes, stormwater chambers, and cellular crates, boxes, or columns. After a large rainfall event, stormwater may need to be collected, detained underground in a void space, and eventually dispersed. The stormwater may be dispersed through the process of infiltration, where the water is temporarily stored and then gradually dissipated through the surrounding earth. Alternatively, the stormwater may be dispersed through the process of attenuation, where the water is temporarily stored and then controllably flowed to a discharge point. Modular crates, boxes, and columns with cells are used for both infiltration and attenuation. These stormwater solutions are buried underground and are covered by soil. The cells of these crates, boxes, and columns provide void space to retain stormwater.
However, stormwater solutions that use cellular crates, boxes, and columns have drawbacks. Once installed underground, these systems are subjected to dead loads (from the soil above them) and live loads (from passing vehicular and pedestrian traffic). The dead and live loads create tensional stress and fatigue on the boxes and crates. To carry the load, the boxes and crates require additional internal supports. These internal supports reduce the amount of void space capable of storing stormwater. To compensate, the boxes or crates must occupy a larger area. The cellular column systems, while able to carry vertical loads, lack lateral support. These systems may be subject to stress and fatigue from soil loads on the sides of the columns.
As an alternative to crates, boxes, or columns, stormwater chambers may be used for stormwater retention and detention. Typically, multiple chambers are buried underground to create large void spaces. Stormwater is directed into the underground stormwater chambers where it is collected and stored. The stormwater chambers allow the stormwater to be temporarily stored and then controllably flowed to a discharge point (attenuation) or gradually dissipated through the earth (infiltration).
However, existing stormwater chambers occupy a large land area for the volume of stormwater storage they provide. Current stormwater chambers may be installed in rows and require large amounts of fill soil or gravel between the rows.
There is a need for a stormwater chamber that has a large storage volume per land area and that has the strength, vertical support, and lateral support to withstand dead and live loads when installed. There is also a need for a stormwater chamber with an open void space that can be entirely filled with stormwater. Additionally, there is a need for stormwater chambers that can be economically installed. For example, it is important to reduce the land area required to be excavated and the fill material needed to cover the chambers. There is also a need for stormwater chambers that can be economically shipped and stored. Specifically, there is a need for a stormwater chamber that is lightweight and stacks well with others.
Accordingly, the stormwater chamber and system of the present disclosure provide improvements over the existing technologies.
In an aspect of the disclosure, a chamber may comprise a chamber body including a chamber wall, an apex, a base, a first opening, and a second opening. The chamber wall may include a continuous curvature from the apex of the chamber body to the first and second openings and a continuous curvature from the apex of the chamber body to the base.
In another aspect of the disclosure, a stormwater management system may comprise at least two chambers coupled together. Each chamber may include a chamber body having a chamber wall, an apex, a base, a first opening, and a second opening. The chamber wall may include a continuous curvature from the apex of the chamber body to the first and second openings and a continuous curvature from the apex of the chamber body to the base. One of the first and second openings of a first chamber may be coupled to one of the first and second openings of a second chamber.
In yet another aspect of the disclosure, a chamber may comprise a chamber body including a chamber wall, an apex, a base, a first opening, and a second opening; a first coupling structure positioned around the first opening; and a second coupling structure positioned around the second opening. The chamber wall may include a continuous curvature from the apex of the chamber body to the base, and the base may curve outward in a horizontal direction from the first and second coupling structures.
Reference will now be made in detail to the exemplary embodiments of the present disclosure described above and illustrated in the accompanying drawings.
Stormwater chamber array 100 may collect and store stormwater. Stormwater chamber array 100 may also allow stormwater to controllably flow to a discharge point (attenuation) or gradually dissipate through the earth (infiltration). Stormwater chamber array 100 may be applicable in various other drainage settings. For example, stormwater chamber array 100 may be utilized in connection with agricultural uses, mining operations, sewage disposal, storm sewers, recreational fields, timber activities, landfill and waste disposal, road and highway drainage, sanitation effluent management, and residential and commercial drainage applications for transporting and draining various types of fluids.
Stormwater chamber array 100 may include individual stormwater chambers aligned in rows. In some embodiments, stormwater chambers 110, 120 may be connected end-to-end together. In one embodiment, stormwater chamber 110 may include a first coupling structure 112 at a first end of stormwater chamber 110 and a second coupling structure 114 at a second end of stormwater chamber 110. Storm water chamber 120 may include a first coupling structure 122 at a first end and a second coupling structure 124 at a second end of stormwater chamber 120. Second coupling structure 114 of stormwater chamber 110 may be connected to first coupling structure 122 of stormwater chamber 120. Second coupling structure 124 of stormwater chamber 120 may be connected to first coupling structure 112 or second coupling structure 114 of an adjacent stormwater chamber. The coupling structures 112, 114, 122, 124 may be coupled together by overlapping or underlapping as described herein. Any number of stormwater chambers 110, 120 may be aligned and connected by coupling structures 112, 114, 122, 124. Rows of stormwater chambers 110, 120 may be configured to receive stormwater from a pipe, chamber, or other drainage component. Stormwater may flow between the stormwater chambers 110, 120 via coupling structures 112, 114, 122, 124. For example, stormwater may flow between stormwater chamber 110 and stormwater chamber 120 via coupling structures 114 and 122.
An end of each row of stormwater chambers may include an endcap to contain the stormwater in the row and prevent intrusion of the surrounding fill material. In one embodiment, coupling structure 112 of stormwater chamber 110 may be fitted with an endcap 130. End cap 130 may be removably attached to coupling structure 112. It should be appreciated that in other embodiments, end cap 130 may be integrally formed with coupling structure 112. In some embodiments, endcap 130 may be a completely solid cap, thereby creating a water-tight seal at the first end of stormwater chamber 110. In other embodiments, endcap 130 may include an opening through which a pipe of an appropriate diameter may fluidly interface with stormwater chamber 110. In other embodiments, endcap 130 may include circular cut lines of various diameters to accommodate a variety of different sized pipes. A user or installer may cut an opening to allow a pipe of a certain diameter to interface with stormwater chamber 110. A pipe that interfaces with stormwater chamber 110 through endcap 130 may deliver stormwater and allow it to enter stormwater chamber 110.
In other embodiments, stormwater chambers 110, 120 may not have coupling structures. Stormwater chambers 110, 120 may be aligned end-to-end with one another but may not be fluidly connected to one another.
As illustrated in
Although not included in the figures, it should be appreciated that the foregoing description and disclosure of stormwater chamber 120 also applies to stormwater chamber 110. Stormwater chamber 120 may be placed on a geotextile covered surface and may be covered in a geotextile. Stormwater chamber 120 may include a chamber body 235 with first and second coupling structures 122 and 124 positioned on opposite sides of chamber body 235. Chamber body 235 may be dome-shaped. Chamber body 235 may include a wall 240 that may curve outward from the apex of chamber body 235 to an open base 270 at the bottom of chamber body 235. Base 270 may curve outward in horizontal directions from first and second coupling structures 122 and 124. Accordingly, in one embodiment, chamber body 235 may include a semi-ellipsoid. It should be appreciated, however, that chamber body 235 may include other dome-shaped configurations such as, for example, a semi-paraboloid, a semi-spheroid, and semi-egg-shaped. It should also be appreciated that a cross sectional shape of chamber body 235 along a horizontal plane above first and second coupling structures 122 and 124 may be substantially circular. In other embodiments, the cross sectional shape may be substantially elliptical.
Stormwater may be stored in the void inside chamber body 235. Chamber body 235 may have a height and width of appropriate dimensions to facilitate a desired volume of stormwater storage. In one embodiment, chamber body 235 may have a height of approximately 60 inches and a width of approximately 90 inches. Accordingly, chamber body 235 may have a storage volume of approximately 140 to 150 cubic feet. It should be appreciated that chamber body 235 may have any other height or width to achieve other desired stormwater storage volumes.
As illustrated in
In the embodiment depicted in
As illustrated in
In some embodiments, the outer surface of wall 240 may be substantially smooth. In other embodiments, the outer surface of wall 240 may contain vertical stiffening ribs. The ribs may be spaced apart around base 270 and outwardly projecting from the outer surface of wall 240. The ribs may extend vertically upward from foot 245 along the outer surface of wall 240. In some embodiments, the ribs may be located on only the lower portion of wall 240. In other embodiments, the ribs may extend to the upper portion of wall 240. In still other embodiments, the ribs may extend over the entire wall 240. In other embodiments, wall 240 may contain corrugations, as described herein. In some embodiments, the top portion of chamber body 235 may include holes, slits, slots, valves, or other openings (not pictured) to allow the release of confined air as stormwater chamber 120 fills with fluid. In some embodiments, top portion of chamber body 235 may include a flat circular surface for accepting an optional inspection port (not pictured). The flat circular surface may be cut out and fitted with an inspection port having a circular cross-section. The inspection port may be opened to allow access to the interior of stormwater chamber 120. The top portion of chamber body 235 may also include a multiplicity of stacking lugs positioned around the flat circular surface and extending upwardly from top portion of chamber body 235.
As discussed above, stormwater chamber 120 may also include first and second coupling structures 122, 124. In some embodiments, first and second coupling structures 122, 124 may be positioned on opposite sides of chamber body 235. It should be appreciated, however, that first and second coupling structures 122, 124 may be positioned in any other suitable configuration relative to each other. For example, in some embodiments, first coupling structure 122 may be positioned substantially perpendicular to second coupling structure 124. First and second coupling structures 122, 124 may be arch-shaped and extend horizontally from the sides of chamber body 235.
As described above, stormwater may flow between stormwater chambers 110, 120 via coupling structures 112, 114, 122, 124. To that end, chamber body 235 may include a first opening 250 and a second opening 280, wherein one of the openings may serve as an inlet into the void of chamber body 235, and the other opening may serve as an outlet from the void of chamber body 235. As shown in
A series of stormwater chambers 110, 120 may be aligned and connected end-to-end by coupling structures 112, 114, 122, 124. For example, coupling structures 122, 124 of stormwater chamber 120 may be arranged to overlap or underlap coupling structures 122, 124 of another stormwater chamber 120. Moreover, coupling structures 122, 124 of stormwater chamber 120 may be arranged to overlap or underlap one of the coupling structures 112 and 114 of stormwater chamber 110. The other coupling structure 112, 114 of stormwater chamber 110 may be coupled to end cap 130. One or both of end corrugations 255 and body corrugations 260 may facilitate the interlocking of coupling structures 122, 124. For example, both end corrugation 255 and body corrugation 260 of coupling structures 122, 124 of stormwater chamber 120 may overlap or underlap end corrugation 255 and body corrugation 260 of coupling structures 122, 124 of another stormwater chamber 120. In other embodiments, only end corrugation 255 of coupling structure 122, 124 of stormwater chamber 120 may overlap or underlap end corrugation 255 of coupling structure 122, 124 of another stormwater chamber 120. When coupling structures 112, 114, 122, 124 are overlapped or underlapped with one another, end corrugations 255 and body corrugations 260 may interface and prevent stormwater chambers 110, 120 from sliding apart. The interlocking of end corrugations 255 (and body corrugations 260 in some embodiments) may also create a water-tight connection between stormwater chambers 110, 120.
It should also be appreciated that end corrugations 255 and body corrugations 260 may facilitate ease and stability of stacking stormwater chambers 110, 120. For storing and shipping, stormwater chambers 110, 120 may be stacked vertically. When stacked, chamber bodies 235 may nest with each other. Coupling structures 112, 114, 122, 124, with their end corrugations 255 and body corrugations 260, may also nest with each other and keep stormwater chambers 110, 120 from sliding during storage and shipping.
Coupling structures 112, 114, 122, 124 may also provide additional storage volume for stormwater chambers 110, 120. The arch-shaped configuration of coupling structures 112, 114, 122, 124 may provide a volume to store stormwater that may enter and/or exit chamber body 235. It should therefore be appreciated that coupling structures 112, 114, 122, 124 may increase the overall storage volume of stormwater chambers 110, 120. In some embodiments, both coupling structures 112, 114 of stormwater chamber 110 and both coupling structures 122, 124 of stormwater chamber 120 may be fitted with endcaps 130 to create single, stand-alone stormwater chambers.
As shown in
In some embodiments, the width of crest corrugations 490 may remain constant with increasing elevation from foot 445. In other embodiments, the width of crest corrugations 490 may decrease with increasing elevation. In some embodiments, the width of valley corrugations 485 may decrease with increasing elevation. In some embodiments, the depth of crest corrugations 490 and valley corrugations 485 may decrease with increasing elevation. In some embodiments, crest corrugations 490 may have a length that terminates on the lower portion of wall 440. In other embodiments, crest corrugations 490 may have a length that terminates on the upper portion of wall 440.
In some embodiments, valley corrugations 485 may terminate on the lower portion of wall 440. In other embodiments, valley corrugations 485 may terminate on the upper portion of wall 440. When crest corrugations 490 reach an elevation greater than the terminal ends of valley corrugations 485, crest corrugations 490 merge with each other and form wall 440. Wall 440 may be smooth at the apex of chamber body 435. In still other embodiments, valley corrugations 485 may extend over the entire wall 440. In some embodiments, the top portion of chamber body 435 may include holes, slits, slots, valves, or other openings to allow the release of confined air as stormwater chamber 420 fills with fluid.
In some embodiments, the corrugations may contain sub-corrugations. Crest corrugations 490 may contain crest sub-corrugations 495. Crest sub-corrugations 495 may be smaller than crest corrugations 490. In some embodiments, the width of crest sub-corrugations 495 may decrease with increasing elevation. In other embodiments, the width of crest sub-corrugations 495 may remain constant with increasing elevation. In some embodiments, the depth of crest sub-corrugations 495 may decrease with increasing elevation. In other embodiments, the depth of crest sub-corrugations 495 may remain constant with increasing elevation. Valley corrugations 485 may contain valley sub-corrugations. Valley sub-corrugations may be smaller than valley corrugations 485. The width and depth of valley sub-corrugations may vary with increasing elevation.
Including crest and valley corrugations may increase the strength of the chamber in both the horizontal and vertical directions. The corrugations may help resist buckling caused by compression forces in the chamber wall. Corrugations may provide this additional strength without adding unnecessary material. Sub-corrugations within the crest corrugations, valley corrugations, or crest and valley corrugations provide additional strength with minimal additional material and weight. The corrugations may provide the additional advantage of securing stormwater chambers when they are stacked vertically and nested with one another.
Stormwater chambers 110, 120, 420 and stormwater chamber array 100 may be utilized for stormwater management applications. Stormwater management may involve determining stormwater levels. Stormwater levels may be determined using a combination of analyzing historical stormwater data, predicting future stormwater totals, and modeling. Stormwater management may also involve determining a desired volume of stormwater storage. Determining the desired volume of stormwater storage may involve determining the minimum, average, median, and maximum anticipated stormwater events for the site.
Stormwater management may also include selecting a number and arrangement of stormwater chambers 110, 120, 420 to accommodate the desired volume of stormwater storage. The number of stormwater chambers 110, 120, 420 may be selected by dividing the total desired volume of stormwater storage by the volume of stormwater storage that an individual stormwater chamber 110, 120, 420 provides. The desired arrangement of stormwater chambers 110, 120, 420 may be determined based on site considerations, including, but not limited to, total land area of the site and the land area and dimensions available for installing stormwater chambers 110, 120, 420. Depending on the desired application, stormwater management may also involve aligning stormwater chambers 110, 120, 420 in rows. The rows may include any number of individual stormwater chambers 110, 120, 420, depending on the drainage application and the desired storage volume. Stormwater management may also include coupling adjacent stormwater chambers 110, 120, 420. In some embodiments, stormwater management may include attaching an endcap 130 to the coupling structure 112 of stormwater chambers 110 at the ends of the rows.
As will be appreciated by one of ordinary skill in the art, the presently disclosed stormwater chamber may enjoy numerous advantages. First, stormwater chamber 110, 120, 420 may provide a stronger stormwater chamber solution than existing stormwater chambers. In particular, the continuously curving, dome shape of chamber body 235, 435 helps distribute dead and live loads around stormwater chamber 110, 120, 420 and shed those loads into the surrounding ground. The continuously curving, dome shape of chamber body 235, 435 may also reduce tensile stress and strain on wall 240, 440 of chamber body 235, 435. Accordingly, chamber body 235, 435 may provide increased strength and durability to stormwater chamber 110, 120, 420.
Second, because stormwater chamber 110, 120, 420 may be stronger due to the shape of chamber body 235, 435, it does not require any additional internal support structures for strength or stability. For example, chamber body 235, 435 may be entirely self-supporting. Because chamber body 235, 435 does not require any internal support structures, the entire volume of chamber body 235, 435 may be used for stormwater storage. Accordingly, stormwater chamber 110, 120, 420 may have a greater storage volume per land area. Reducing the land area required for a single stormwater chamber 110, 120, 420 or an array of stormwater chambers 100 has many of its own advantages, including reducing the costs associated with excavation, including time, labor, and expense.
Third, because the continuously curving, dome shape of chamber body 235, 435 may allow an array of stormwater chambers 110, 120, 420 to be positioned closer together, less fill material may be required between and above stormwater chambers 110, 120, 420. This may also reduce material and labor costs.
Finally, coupling structures 112, 114, 122, 124, 422, 424 of stormwater chambers 110, 120, 420 may provide versatility and modularity. Coupling structures 112, 114, 122, 124, 422, 424 may allow for any number of stormwater chambers 110, 120, 420 to be aligned end-to-end to create a row of stormwater chambers. In other embodiments, endcaps 130, 430 may be connected to coupling structures 112, 114, 122, 124, 422, 424 to create a single, stand-alone stormwater chamber.
The many features and advantages of the present disclosure are disclosed in the detailed specification. Thus, it is intended by the appended claims to cover all such features and advantages of the present disclosure which fall within the true spirit and scope of the present disclosure. Further, since numerous modifications and variations will readily occur to those skilled in the art, it is not desired to limit the present disclosure to the exact construction and operation illustrated and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the present disclosure.
Number | Name | Date | Kind |
---|---|---|---|
3897298 | Gray | Jul 1975 | A |
4655013 | Ritland | Apr 1987 | A |
D337832 | Dunne | Jul 1993 | S |
5341610 | Moss | Aug 1994 | A |
5485701 | Hecht | Jan 1996 | A |
7744756 | Davis, Jr. | Jun 2010 | B2 |
8672583 | Mailhot | Mar 2014 | B1 |
9371938 | Miskovich | Jun 2016 | B2 |
20030115809 | Pontarolo | Jun 2003 | A1 |
20030219310 | Burnes | Nov 2003 | A1 |
20040101369 | DiTullio | May 2004 | A1 |
20060233612 | DiTullio | Oct 2006 | A1 |
20070053746 | Dickie | Mar 2007 | A1 |
20090025306 | Reed | Jan 2009 | A1 |
20090220302 | Cobb | Sep 2009 | A1 |
20100329787 | Moore, Jr. | Dec 2010 | A1 |
20110308648 | Polk et al. | Dec 2011 | A1 |
20150260313 | Miskovich | Sep 2015 | A1 |
20160281347 | Miskovich | Sep 2016 | A1 |
20160369490 | Rotondo | Dec 2016 | A1 |
Number | Date | Country |
---|---|---|
WO 2010090755 | Aug 2010 | WO |
Number | Date | Country | |
---|---|---|---|
20180100300 A1 | Apr 2018 | US |