The embodiments described herein relate to a roof drain, and more particularly, to a roof drain having improved drainage and flow characteristics.
Commercial buildings are typically constructed with flat or near flat roofs. Because these building do not have much of a pitch, the collection of water on the roof surface from rain or melting snow can present serious structural loads that could result in collapse. To avoid this possibility, most commercial and industrial building standards require that roofs of this type include drains positioned at locations that ensure the water accumulated thereon can be removed in a timely manner.
In one embodiment, a roof drain including a base defining a channel and an axis, a gravel guard coupled to the base and including a plurality of teeth, where the gravel guard defines a plurality of gullets between the teeth, and a dome coupled to the base, where the dome includes a plurality of ribs, where the ribs define a plurality of gaps therebetween, and where each gap is radially aligned with a corresponding gullet.
In another embodiment, a roof drain including a base defining an axis, the base having a throat portion and a flange portion extending radially outwardly from the throat portion, where the throat portion at least partially defines a channel therethrough having an outlet, and where the flange portion includes an outer edge and a top plane, a gravel guard coupled to the base and including a plurality of teeth, where the gravel guard defines a plurality of gullets, and where at least a portion of each gullet is positioned axially below the top plane, and a dome coupled to the base.
In another embodiment, a roof drain including a base at least partially defining a channel therethrough, where the channel includes an inlet and an outlet defining an outlet diameter, and where the base defines a top plane, a gravel guard coupled to the base and including a plurality of teeth and a plurality of gullets positioned between adjacent teeth, and a dome coupled to the base, where the roof drain is configured to flow between 75 GPM and 150 GPM through the channel at 1″ of head pressure measured relative to the top plane.
In another embodiment, A roof drain including a flange defining an opening having a central axis, and a throat extending axially from the flange to define a channel having an inner surface therethrough. Where the throat includes a first end generally corresponding with the flange, and a second end opposite the first end, and where the second end is configured to be coupled to a drain outlet. The inner surface of the channel includes a cross-sectional shape taken normal to the central axis, and where the cross-sectional shape continuously and smoothly decreases or remains the same from the first end to the second end.
In another embodiment, a roof drain including a body defining a central axis and a channel having an inner surface, where the channel includes a first end and a second end opposite the first end, where the second end is configured to be coupled to a drain outlet, and where the inner surface of the channel defines a cross-sectional shape taken parallel to the axis, and where the cross-sectional shape is at least partially convex.
In another embodiment, a roof drain including a body defining a central axis and a channel having an inner surface, where the channel includes a first end and a second end where the first end, where the second end is configured to be coupled to a drain outlet, and where the inner surface of the channel defines a first surface angle relative to the central axis at the first end and a second surface angle relative to the central axis at the second end, and where the first surface angle is greater than the second surface angle.
In another embodiment, a roof drain including a body defining a central axis and a channel having an inner surface, where the channel includes a first end and a second end opposite the first end, where the second end is configured to be coupled to the drain outlet; and where the inner surface of the channel defines a surface angle relative to the central axis at each location between the first end and the second end, and where the surface angle smoothly transitions from the first end to the second end while always decreasing or staying the same in value.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.
The base 5004 also includes a series of threaded apertures 5044 positioned at least partially within the “bowl” and spaced radially inwardly from the teeth 5048 of the gravel guard 5012.
The gravel guard 5012 of the roof drain 5000 rests against the flange portion 2036 of the base 5004 and includes a series of teeth 5048, and a plurality of bolt apertures 5052 spaced radially inwardly from the teeth 5048. The gravel guard 5012 also includes a plurality of gullets 5060 positioned between the teeth 5048 that are positioned vertically above the finished surface 5108 of the adjacent roof 5100 and vertically above the outer edge 5040 of the base 5004. The gullets 5060 are also positioned above the top surface 5064 of the gravel guard body 5068. When assembled, the gravel guard 5012 is secured to the base 5004 with fasteners 5072 extending through the bolt apertures 5052 and threaded into the threaded apertures 5044 of the base 5004.
As shown in
The base 18 of the drain 10 is substantially “funnel” shaped defining the channel 38 through which rainwater may be directed into the plumbing system 34 of the building. More specifically, when rainwater collects on the roof 14, the water flows into the inlet 40 of the channel 38 where it is directed into the plumbing or drain system 34 via the outlet 22 thereof. In the illustrated embodiment, the base 18 includes a throat portion 42 at least partially defining the channel 38, and a flange portion 46 extending radially outwardly from the throat portion 42. Together, the throat portion 42 and flange portion 46 define a central axis 50. While the illustrated base 18 is cast as a single piece of material, it is to be understood that in alternative embodiments, the base 18 may be formed as multiple pieces coupled together.
The throat portion 42 of the base 18 is formed from a substantially annular wall 54 having an inner surface 58, a first end 62 generally corresponding with the inlet 40 of the channel 38, and a second end 66 opposite the first end 62 that generally corresponds with and forms the outlet 22 of the channel 38. The inner surface 58 is shaped such that the inner diameter 72 of the inner surface 58 continuously and smoothly decreases as it extends axially away from the first end 62 and toward the second end 66. More specifically, the cross-sectional shape of the inner surface 58, taken along the axis 50, forms a substantially convex shape over its entire axial length (see
The inner surface 58 of the throat portion 42 forms a first surface angle 80a relative to the axis 50 at the first end 62 thereof and a second surface angle 80b relative to the axis 50 at the second end 66 thereof (see
While the illustrated inner surface 58 provides a smooth, curved, convex shape, it is to be understood that alternative shapes may also be used. For example,
The flange portion 46 of the base 18 extends radially outwardly from the first end 62 of the throat portion 42 to produce an outer edge 92. The outer edge 92, in turn, defines a top plane 96 (e.g., generally oriented normal to the axis 50 and positioned at the axial highest point of the base 18), and an outer diameter 100. The flange portion 46 includes a first portion 104 extending radially inwardly from the outer edge 92 at a first surface angle 108 relative to the axis 50, a second portion 112 extending radially inwardly from the first portion 104 at a second surface angle 116 relative to the axis 50, and a third portion 120 extending radially inwardly from the second portion 112 at a third surface angle 124. As shown in
When installed, the top plane 96 of the flange portion 46 is generally positioned so that is aligned with the top surface 130 of the roof 14 positioned immediately adjacent thereto. As such, any roof membrane or paper 152 can transition from the roof 14 to the base 18 without producing any high spots or bumps. For the purposes of this application, the top surface 130 of the roof 14 is generally defined as the surface upon which the roof paper 152 is laid (e.g., the top surface of the concrete) and does not include any gravel positioned thereon. Stated differently, the top surface 130 is substantially aligned with the top plane 96. In alternative embodiments, the roof drain 10 may be mounted to a deck plate or other installation apparatus whereby the top surface 130 may include the upper surface of the deck plate upon which the roof paper 152 is laid proximate the roof drain 10.
When the drain 10 is assembled, the second portion 112 and second surface angle 116 are generally configured to match the angle and radial width of the underside of the gravel ring 30 (described below). Similarly, the third portion 120 and third surface angle 124 are generally set to match with the angle and radial size of the underside of the dome 26. (See
As shown in
By elevating the outer edge 92 as described above, the drain 10 is configured so that water entering the drain 10 by flowing over the outer edge 92 (e.g., with the outer edge 92 installed level with the roof 14; see
The base 18 also includes a first plurality of threaded apertures 136 formed into the flange portion 46 and outside the channel 38. During use, the threaded apertures 136 are configured to receive a threaded fastener 140 therein to couple the gravel ring 30 to the base 18. Similarly, the base 18 includes a second plurality of threaded apertures 144 on the underside thereof for securing the base 18 to the roof 14 or other building structure.
The base 18 also includes a cutting groove 148. The cutting groove 148 is formed into the base 18 at a first radial distance from the axis 50. During use, the cutting groove 148 is configured to receive and guide the tip of a knife or razor blade therein so the user can quickly and easily trim the roof paper 152 at the desired location. In the illustrated embodiment, the cutting groove 148 includes a “step” having two adjacent surfaces against which the user's blade may be pressed (e.g., into the corner formed by the two surfaces). However, in alternative embodiments, the groove 148 may be enclosed on three sides (not shown). In still other embodiments, the cutting groove 148 may include other shapes and contours desirable to directing the user during the cutting process. While the illustrated groove 148 is annular in shape, in alternative embodiments, alternative shapes (e.g., polygonal, stepped, and the like) may also be present to produce the desired final cut dimensions. As shown in
As shown in
Illustrated in
The dome 26 is substantially cylindrical in shape having an upper surface 160 and a side surface 164 extending along the perimeter for the upper surface 160. The dome 26 also includes a core element 168 defining a central axis 172, a plurality ribs 176 extending radially outwardly from the core element 168, and a plurality of crossbars 180 extending between and interconnecting select adjacent ribs 176. The core element 168 of the dome 26 is substantially disk shaped having a central disk 184 defining a plurality of apertures 188 therein, a concentric ring 192 spaced radially outward from the central disk 184, and a plurality of splines 196 extending radially between the central disk 184 and the concentric ring 192. The core element 168 also defines an outer core diameter 200. In alternative embodiments, additional styles and shapes of core elements may be present such as, but not limited to, a solid or perforated disk, a dish-shaped element, a plurality of concentrically located rings, a plurality of radially or otherwise oriented splines, and the like.
The ribs 176 of the dome 26 each extend radially outwardly from the core element 168 to produce a respective distal end 204. Together, the ribs 176 are generally spaced equally from one another in a circumferential direction to produce a plurality of equally sized gaps 208 therebetween. Each rib 176, in turn, includes a first leg or portion 212 extending radially outwardly from the core element 168, and a second leg or portion 216 extending from the first leg 212 at an angle with respect thereto to produce the distal end 204. Each rib 176 also includes a bend or transition 220 where the first leg 212 and second leg 216 meet.
As shown in
The crossbars 180 of the dome 26 extend between and are coupled to adjacent ribs 176. Each crossbar 180 is generally positioned at various locations along the lengths of the ribs 176 and oriented substantially perpendicular thereto. As shown in
In the illustrated embodiment, the dome 26 includes a first set of crossbars 1180 and a second set of crossbars 2180. Each crossbar 1180 of the first set of crossbars extends between the first legs 212 of the ribs 176 and are each located at a first radial distance 224 from the axis 172. As shown in
Each crossbar 2180 of the second set of crossbars extends between the second legs 216 of the ribs 176 at a corresponding “bar height” 228. For the purposes of this application, the bar height 228 is generally defined as the distance between the crossbar 180 and the distal end 204 of the corresponding rib 176.
The second set of crossbars 2180 are generally positioned so that they alternate above and below a datum plane 232 oriented normal to the axis 172 and located at a predetermined datum height 236. For the purposes of this application, the datum height 236 is generally defined as the axial distance between the datum plane 232 and the base plane 240 of the dome 26 (described below). In some embodiments, the datum plane 232 may be positioned at the midpoint such that the datum height 236 is half the overall axial height 244 of the dome 26. In other embodiments, the datum plane 232 may be positioned at different datum heights 236 to accommodate different flow patterns.
As shown in
More specifically, the second set of crossbars 2180 are positioned to produce a repeating pattern about the circumference of the dome 26. Specifically, the first crossbar 2180a of the pattern includes a first bar height 228a, the subsequent second crossbar 2180b has a second bar height 228b that is greater than the first bar height 228a, the subsequent third crossbar 2180c has a third bar height 228c that is less than the second bar height 228b, the subsequent fourth crossbar 2180d has a fourth bar height 228d that is greater than the third bar height 228c, the subsequent fifth crossbar 2180e has a fifth bar height 228e that is less than the fourth bar height 228d, and the subsequent sixth crossbar 2180f has a sixth bar height 228f that is greater than the fifth bar height 228e. In instances where six crossbars 2180 are included in the pattern, the sixth bar height 228f is also greater than the first bar height 228a. However, in alternative embodiments, additional or fewer crossbars 2180 may be included in the pattern as necessary (e.g., four crossbars, five crossbars, seven crossbars, eight crossbars, nine crossbars, and the like).
As shown in
While the illustrated crossbars 180 are oriented as described above, it is understood that additional patterns may be present. Furthermore, the pattern may be expanded to include more or fewer crossbars 180 as necessary and to accommodate different numbers of ribs 176 and dome 26 sizes.
The dome 26 also includes a set of base plates 132, each coupled to the distal end 204 of one or more ribs 176 and configured to support the dome 26 on the base 18. In the illustrated embodiment, the base plates 132 do not completely enclose the bottom of the dome 26, rather, at least one of the gaps 208 between adjacent ribs 176 are open (e.g., not enclosed at the bottom of the dome 26). When the drain 10 is assembled, the base plates 132 are positioned completely axially below the top plane 96. Furthermore, the gaps between the base plate 132 also extend axially below the top plane 96. As shown in
As shown in
The first set of base plates 1132 are each substantially elongated in shape extending along and being coupled to one or more distal ends 204 of the ribs 176. During use, the first set of base plate 1132 generally form locking members 256 and are configured to interact with and releasably couple to the gravel ring 30. In the illustrated embodiment, the dome 26 includes three first base plates 1132, each positioned so that they generally correspond and align with a respective locking member 260 of the gravel ring 30 (described below).
The locking members 256 of the dome 26 are configured to both restrict the axial movement of the dome 26 relative to the base 18 (e.g., clamp the dome 26 to the base 18) and rotationally orient the dome 26 relative to both the base 18 and gravel ring 30. As shown in
The second set of base plates 2132 are each configured to strengthen and enclose adjacent ribs 176 of the dome 26. As shown in
As shown in
The body 270 of the gravel ring 30 is annular in shape and defines an outer diameter 290, an inner diameter 294, and an upper surface 296. As shown in
The locking members 260 of the gravel ring 30 are configured to releasably engage with the locking members 256 of the dome 26. More specifically, the locking members 260 of the gravel ring 30 are configured to axially lock the dome 26 against the base 18 while also rotationally aligning the ring 30, dome 26, and base 18. In the illustrated embodiment, the locking members 260 of the gravel ring 30 include a plurality of tabs extending radially inwardly from the body 270 to produce a distal end 304 at a distal end diameter 308. As shown in
The teeth 286 of the gravel ring 30 extend axially from upper surface 296 of the body 270 and are spaced in equal groups about the circumference thereof. More specifically, the illustrated teeth 286 include six groups of six equally spaced teeth 286, each separated by a corresponding bolt aperture 312. Together, the teeth 286 and bolt apertures 312 are all equally spaced about the circumference of the gravel ring 30 and generally located at the same radial distance from the axis 278 (e.g., on the same reference circle centered on the axis 278). As such, when the gravel ring 30 is installed, the head 314 of the fasteners 318 positioned in the bolt apertures 312 serve to act as a “tooth” in the gravel ring 30. By doing so, the fasteners 318 are both easily accessible by the user while minimizing any restrictions to the water flow past the ring 30 itself. As shown in
As shown in
Each tooth 286 also includes a leading angle 328 and a trailing angle 332. For the purposes of this application, the leading angle 328 is generally defined as the angle at which the tooth 286 extends from the leading point 316 while the trailing angle 332 is generally defined as the angle at which the tooth 286 extends from the trailing point 320. As shown in
The gravel ring 30 also includes a plurality of gullets 128 formed between a corresponding pair of teeth 286, between a tooth 286 and bolt aperture 312 (e.g., the head 314 of the fastener 318 positioned in the bolt aperture 312), or between a tooth 286 and a locking member 260. The gullets 128, are equally spaced about the entire circumference of the gravel ring 30, including those gullets 128 associated with the bolt apertures 312 and locking members 260.
Each gullet 128, in turn, includes a low point or bottom 336. In the illustrated embodiment, the low point 336 of the gullets 128 lie directly on the upper surface 296 of the body 270. As shown in
In the illustrated embodiment, the number of gullets 128 on the gravel ring 30 and the number of gaps 208 in the dome 26 are multiples of one another. As such, when both the gravel ring 30 and dome 26 are attached to the base 18 (and rotationally aligned using the locking members 256, 260), each of the gullets 128 may be radially aligned with a corresponding gap 208 (e.g., when the number of gullets 128 is less than or equal to the number of gaps 208) or each gap 208 may be radially aligned with a corresponding gullet 128 (e.g., when the number of gaps 208 is less than or equal to the number of gullets 128). This arrangement allows for a more efficient and direct flow path for water to enter the channel 38 during use. In the illustrated embodiment, the number of gullets 128 equals the number of gaps 208.
While the illustrated drain 10 is shown being substantially circular in shape, it is understood that in alternative embodiments, the drain 10 may be rectangular, square, oval, or polygonal in shape.
To install the drain 10 on a roof 14, the user places the base 18 such that the outer edge 92 of base 18 is located substantially level with the top surface 130 of the roof 14 (e.g., the top plane 96 is aligned with the top surface 130; see
With the base 18 in place, the user may then apply a layer of roof paper 152 to the top surface 130 of the roof 14. When doing so, the user lays the paper 152 over the outer edge 92 so it generally covers the base 18. With the paper 152 roughly positioned, the user may then attach the gravel ring 30 to the base 18. To do so, the user axially places the gravel ring 30 onto the flange portion 46, making sure to align the bolt apertures 312 of the ring 30 with the corresponding threaded apertures 136 of the base 18. The user may then secure the ring 30 to the base 18 using a series of threaded fasteners 318 (see
With the ring 30 in place, the user may then trim the roof paper 152 by running a blade (e.g., a razor blade or knife) along the cutting groove 148 of the base 18. By doing so, the cutting groove 148 will guide the blade along the desired cutting path, allowing the user to remove the portion of the paper 152 generally covering the channel 38. As described above, the cutting groove 148 is positioned such that the appropriate length and shape of paper 152 remains attached to the drain 10 as required by code. Furthermore, the notches 300 of the gravel ring 30 are positioned such that an increased length of roof paper 152 is exposed after the excess paper has been removed (e.g., the exposed radial length of paper 152 equals the radius of the interior of the notch 300 minus the radius at which the cutting groove 148 is located).
Finally, the user may install the dome 26. To do so, the user aligns each locking member 260 of the gravel ring 30 with a corresponding locking member 256 of the dome 26. More specifically, the user aligns the elements to that the of the gravel ring 30 with a corresponding locking notch 266 of the dome 26. The dome 26 is then axially directed onto the base 18 until the bottom surfaces 252 of the dome 26 contacts the flange portion 46 of the base 18. By doing so, each locking member 260 passes through their corresponding notch 266.
Once in place, the user can then rotate the dome 26 relative to the base 18 and gravel ring 30 causing each locking member 260 to pass over the top of its corresponding base plate 132 until each locking member 260 contacts a respective locking ridge 264. With the locking member 260 in contact with the ridge 264, the dome 26 and ring 30 are rotationally aligned such that the gullets 128 of the ring 30 radially align with the gaps 208 of the dome 26.
The gravel ring 30′ includes a plurality of teeth 286′ having a substantially chevron shape. More specifically, each tooth 286′ includes a leading surface 1000′ positioned proximate to and facing the outer diameter 290′ of the ring 30′ body 270′, and a trailing surface 1004′ opposite the leading surface 1000′ and facing the inner diameter 294′ of the body 270′. Each tooth also narrows as it extends axially from the body 270′.
The leading surface 316′ is substantially convex, extending outwardly away from the tooth 286. In the illustrated embodiment the leading surface 316′ includes a pair of planar surfaces set at an angle relative to one another to form a point 1008′ and facing radially outwardly. More specifically, the planar surfaces are oriented such that they extend away from each other as they extend radially inwardly. In alternative embodiments, the leading surface 316′ may include a single, convex curved surface as well.
The trailing surface 1004′ is substantially concave, extending inwardly into the tooth 286. In the illustrated embodiment, the trailing surface 1004′ includes a curved concave surface. However, in alternative embodiments multiple planar surfaces may also be used.
The gullets 128′ of the ring 30′ each include a low point or bottom 336″ that, when installed on a base 18, is below the top plane 96. In the illustrated embodiment, the bottom 336′ of the gullet 128′ is coincident with the top surface 296′ of the body 270′. Furthermore, the illustrated ring 30″ includes the same number of gullets 128′ as the number of gaps 208 in the dome 26. In alternative embodiments, the ring 30′ may include a number of gullets 128′ that is a multiple of the number of gaps 208 in the dome 26.
The gullets 128″ of the ring 30″ each include a low point or bottom 336″ that, when installed on a base 18, is below the top plane 96. In the illustrated embodiment, the bottom 336″ of the gullet 128″ is coincident with the top surface 296″ of the body 270″. Furthermore, the illustrated ring 30″ includes the same number of gullets 128″ as the number of gaps 208 in the dome 26. In alternative embodiments, the ring 30″ may include a number of gullets 128″ that is a multiple of the number of gaps 208.
The teeth 286″ of the ring 30″ are substantially rectangular in shape having a wider circumferential dimension than radial dimension. Each tooth 286″ also narrows as it extends axially from the top surface 296″ of the body 270″. While the illustrated teeth 286″ are rectangular, in alternative embodiments, different shapes may be used. In still other embodiments, the size and shape of the teeth 286″ may vary on a single ring 30″ (e.g., a portion of the teeth 286″ are rectangular, a portion are diamond, and the like).
In still other embodiments, the drain 10 is configured to flow between 40 and 120 GPM at 1″ of head pressure with an output diameter 24 of 2″. In another embodiment, the drain 10 is configured to flow between 80 and 180 GPM at 1″ of head pressure with an output diameter 24 of 2″. In still other embodiments, the drain 10 is configured to flow between 90 and 110 GPM at 1″ of head pressure with an output diameter 24 of 2″. In still other embodiments, the drain 10 is configured to flow approximately 100 GPM at 1″ of head with an output diameter 24 of 2″.
In still other embodiments, the drain is configured to flow between 225 and 400 GPM at 2″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 225 and 375 GPM at 2″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 300 and 400 GPM at 2″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 350 and 400 GPM at 2″ of head with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow approximately 350 GPM at 2″ of head with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow greater than 225 GPM at 2″ of head pressure with an outlet of 4″. In still other embodiments, the drain 10 is configured to flow at least 250 GPM at 2″ of head pressure with an outlet diameter of 4″. In still another embodiment, the drain 10 is configured to flow at least 250 GPM at 2″ of head with an outlet of at least 3″.
In still other embodiments, the drain 10 is configured to flow between 200 and 350 GPM at 2″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow between 200 and 325 GPM at 2″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow between 300 and 400 GPM at 2″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow between 300 and 350 GPM at 2″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow approximately 325 GPM at 2″ of head pressure with an outlet diameter of 3″. In still other embodiments, the drain 10 is configured to flow greater than or equal to 325 GPM at 2″ of head pressure with an outlet diameter of 3″. In still other embodiments, the drain 10 is configured to flow at least 200 GPM at 2″ of head pressure with an outlet diameter of 3″.
In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 2″ of head pressure. For the purposes of this application, the maximum flow rate of the drain 10 is generally defined as the maximum rate of flow that can pass through the drain 10 having a downpipe with a diameter equal to the outlet diameter 24 of the outlet 22 attached thereto.
In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 2″ of head pressure with an outlet diameter of 2″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at between 1″ and 2″ of head pressure with an outlet diameter of 2″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at 1.5″ of head pressure or less with an outlet diameter 24 of 2″. In still other embodiments, the roof drain is configured to reach 90% maximum flow rate at less than 2″ of head pressure with an outlet diameter of 2″.
In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 5″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at between 3″ and 4″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at between 3.5″ and 4″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at approximately 3.5″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 4″ of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured reach 90% maximum flow rate at less than 4.5″ of head pressure with an outlet diameter of 4″.
In still some embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 4″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 3″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at between 2″ and 3″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at between 2.5″ and 3″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at approximately 2.5″ of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to reach 90% maximum flow rate at less than 3.5″ of head pressure with an outlet diameter of 3″.
In some embodiments, the flow rates set forth above may be determined by attaching a 10 foot long vertically oriented downpipe to the outlet 22 of the drain 10 and then running a test measuring the flow rate through the drain 10 and downpipe. In such embodiments, the 10 foot long vertically oriented downpipe would have a size substantially corresponding to the outlet diameter 24 of the drain 10. Furthermore, in some embodiments the roof drain may be installed in a test stand according industry standard ASME A112.6.4. Similarly, a test protocol to gather the data may also be conducted in accordance with ASME A112.6.4.
In some embodiments, the drain 10 is configured to flow between 80 GPM and 125 GPM at 1 inch of head pressure. In still other embodiments, the drain 10 is configured to flow between 150 GPM and 445 GPM at 2 inches of head pressure. In still other embodiments, the drain 10 is configured to flow between 300 GPM and 350 GPM at 2 inches of head pressure. In still other embodiments, the drain 10 is configured to flow between 310 GPM and 330 GPM at 2 inches of head pressure.
In some embodiments, the drain 10 is configured to flow between 80 and 90 GPM at 1 inch of head pressure with an outlet diameter 24 of 2″. In still other embodiments, the drain 10 is configured to flow approximately 85 GPM at 1 inch of head pressure with an outlet diameter 24 of 2″. In still other embodiments, the drain 10 is configured to flow between 140 and 150 GPM with an outlet diameter 24 of 2″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at less than 1.5 inches of head pressure and an outlet diameter 24 of 2″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at less than 1.28 inches of head pressure and an outlet diameter 24 of 2″.
In some embodiments, the drain 10 is configured to flow between 80 and 150 GPM at 1 inch of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow approximately 81 GPM at 1 inch of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow between 310 and 350 GPM at 2 inches of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow approximately 320 GPM at 2 inches of head pressure with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow between 320 and 400 GPM with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow between 340 and 360 GPM with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to flow approximately 360 GPM with an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at 2 inches or less of head pressure and an outlet diameter 24 of 3″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at 3 inches or less of head pressure and an outlet diameter 24 of 2″.
In some embodiments, the drain 10 is configured to flow between 80 and 100 GPM at 1 inch of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow approximately 81 GPM at 1 inch of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 300 and 600 GPM at 2 inches of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 300 and 350 GPM at 2 inches of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow approximately 314 GPM at 2 inches of head pressure with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 600 and 650 GPM with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow between 620 and 350 GPM with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to flow approximately 630 GPM with an outlet diameter 24 of 4″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at 3 inches or less of head pressure and an outlet diameter 24 of 4″.
In some embodiments, the drain 10 is configured to flow between 100 and 130 GPM at 1 inch of head pressure with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to flow approximately 102 GPM at 1 inch of head pressure with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to flow between 350 and 700 GPM at 2 inches of head pressure with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to flow between 375 and 425 GPM at 2 inches of head pressure with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to flow approximately 400 GPM at 2 inches of head pressure with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to flow between 1400 and 1600 GPM with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to flow approximately 1500 GPM with an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at 4 inches or less of head pressure and an outlet diameter 24 of 6″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at 4.5 inches of head pressure and an outlet diameter 24 of 6″.
In some embodiments, the drain 10 is configured to flow between 100 and 130 GPM at 1 inch of head pressure with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to flow approximately 122 GPM at 1 inch of head pressure with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to flow between 400 and 500 GPM at 2 inches of head pressure with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to flow between 420 and 480 GPM at 2 inches of head pressure with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to flow approximately 440 GPM at 2 inches of head pressure with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to flow between 2000 and 2500 GPM with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to flow approximately 2300 GPM with an outlet diameter 24 of 8″. In still other embodiments, the drain 10 is configured to achieve 90% maximum flow at 5.5 inches or less of head pressure and an outlet diameter 24 of 8″.
As shown in
The drain 3010 also includes one or more connection members 3524 configured to releasably secure the drain 3010 to a roof 14, alignment plate (not shown) or other support surface. Each connection member 3524 includes a first leg 3536 and a locking flange 3540. As shown in
As shown in
The drain 3010 also includes a plurality of stand-offs 3548 extending axially from the underside 3504 of the base 3018. The stand-offs 3548 are substantially cylindrical in shape and positioned equally along the outer edge 3092 of the base 3018. During use, the stand-offs 3548 are configured to engage the roof 14 or support surface and secure the base 3018 relative thereto.
As shown in
The first set of base plate 3132 also includes a locking notch 3560 formed into the upper side 3554 of the base plate 3132. When assembled, the locking notch 3560 substantially aligns with a corresponding aperture 3564 of the locking member 3260 such that the user may insert a fastener or pin through the aperture 3564 where it is at least partially received within the locking notch 3560 to rotational lock the cage 3026 relative to the ring 3030.
Although the invention has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of one or more independent aspects of the invention as described.
The present application is a continuation of U.S. patent application Ser. No. 17/192,688, filed Mar. 4, 2021, which claims priority to U.S. Provisional Patent Application No. 63/009,894, filed Apr. 14, 2020. The entire contents of both of which are hereby incorporated by reference.
Number | Date | Country | |
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63009894 | Apr 2020 | US |
Number | Date | Country | |
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Parent | 17192688 | Mar 2021 | US |
Child | 17566985 | US |