Sprinkler head nozzle assembly with adjustable arc, flow rate and stream angle

Abstract

A sprinkler head nozzle assembly in accordance with an embodiment of the present invention includes an adjustable nozzle operable to extend and reduce an arcuate opening wherein the size of the arcuate opening indicates the arc of coverage of the sprinkler head nozzle assembly and a rotating distributor, mounted on a central shaft extending through the housing and the nozzle member, and operable to deflect a flow of water from the arcuate opening out of the nozzle assembly.

Claims

1. A sprinkler assembly comprises: a base; a nozzle element mounted in the base and including an arcuate opening through which a stream of water passes; an arc of coverage adjustment element mounted in the base and operatively connected to the nozzle element and accessible from an exterior of the sprinkler assembly to expand and contract the arcuate opening in the nozzle element to adjust an arc of coverage provided by the stream of water provided by the nozzle element; a shaft extending through the base, the nozzle element, and the arc of coverage adjustment element and extending above the base, wherein the shaft is mounted to be axially movable relative to the base, the nozzle element and the arc of coverage adjustment element, such that the shaft moves upward and downward independent of the nozzle element and the arc of coverage adjustment element; and a rotating distributor mounted on a top end of the shaft and rotatable with respect thereto, the rotating distributor positioned to receive the stream of water and distribute the water outward and away from the nozzle assembly in the arc of coverage.

2. The sprinkler head nozzle assembly of claim 1, wherein the nozzle element further comprises: a lower stationary valve element including: a cylindrical lower portion; a conical upper portion, the conical upper portion including: a stepped and spiraled top surface; a radially extending rib; a disk shaped middle element including one or more openings formed therein around a portion of the disk shaped middle element; and an upper element rotatably mounted on the disk shaped middle element, the upper element including: a vertically extending element extending from a top surface of the upper element, wherein the vertically extending element rotates between a first position and a second position to vary a length of the arcuate opening defined between the vertically extending element and the radially extending rib to vary the arc of coverage of the sprinkler assembly.

3. The sprinkler assembly of claim 2, wherein the upper element is operatively connected to the arc of coverage adjustment element such that movement of the arc of coverage adjustment element moves the vertically extending element relative to the radially extending rib to expand and contract the arcuate opening.

4. The sprinkler assembly of claim 3, further comprising an interim arc adjustment mechanism positioned between and connected to the arc of coverage adjustment element and the upper element.

5. The sprinkler assembly of claim 4, wherein the interim arc adjustment mechanism is mounted in the base.

6. The sprinkler assembly of claim 4, wherein the interim arc adjustment mechanism comprises: a vertically extending sidewall extending upward around a periphery of a top surface thereof and including at least one slot formed therein, the slot configured to receive a portion of the arc of coverage adjustment mechanism; and a horizontal flange extending inward around a central opening, the horizontal flange including at least one notch configured to receive a portion of the upper element such that the interim arc adjustment element rotates with the arc of coverage adjustment element and the upper element.

7. The sprinkler assembly of claim 1 further comprising a flow control element operably connected to the base and accessible from an exterior of the nozzle assembly, the flow control element configured to adjust a flow of water to the nozzle element.

8. The sprinkler assembly of claim 7, wherein the shaft extends through the flow control element.

9. The sprinkler assembly of claim 7, wherein the flow control element comprises: a lower stationary portion; and an upper rotatable ring mounted in the lower stationary portion such that rotation of the upper rotatable ring relative to the lower stationary portion adjusts an amount of water that flow to the nozzle element.

10. The sprinkler assembly of claim 9, wherein the lower stationary portion comprises a lower portion including at least one first flow opening and the upper rotatable ring includes a lower portion include at least a second flow opening.

11. The sprinkler assembly of claim 10, wherein the upper rotatable ring is rotatable from a first position in which the first flow opening is aligned with the second flow opening to allow flow of water and a second position in which the first flow opening is out of alignment with the second flow opening to disrupt the flow of water.

12. A sprinkler assembly comprises: a base; a nozzle element mounted in the base and including an arcuate opening through which a stream of water passes, wherein the nozzle element further comprises: a lower stationary valve element including: a cylindrical lower portion; a conical upper portion, the conical upper portion including: a stepped and spiraled top surface; a radially extending rib; a disk shaped middle element including one or more openings formed therein around a portion of the disk shaped middle element; and an upper element rotatably mounted on the disk shaped middle element, the upper element including: a vertically extending element extending from a top surface of the upper element, wherein the vertically extending element rotates between a first position and a second position to vary a length of the arcuate opening defined between the vertically extending element and the radially extending rib to vary the arc of coverage of the sprinkler assembly; an arc of coverage adjustment element mounted in the base and operatively connected to the nozzle element and accessible from an exterior of the nozzle assembly to expand and contract the arcuate opening in the nozzle element to adjust an arc of coverage provided by the stream of water provided by the nozzle element; a shaft extending through the base, the nozzle element, and the arc of coverage adjustment element and extending above the base, the shaft axially movable relative to the base; and a rotating distributor mounted on a top end of the shaft and rotatable with respect thereto, the rotating distributor positioned to receive the stream of water and distribute the water is outward and away from the nozzle assembly in the arc of coverage.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 shows a cross-sectional side elevation view of a sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(2) FIG. 1a illustrates a cross-sectional view of the sprinkler head nozzle assembly of FIG. 1 mounted in a sprinkler body in accordance with an embodiment of the present invention;

(3) FIG. 2 shows a cross-sectional side elevation view of the sprinkler head nozzle assembly of FIG. 1 with a distributor in a raised position in accordance with an embodiment of the present invention;

(4) FIG. 3 illustrates a detailed view of a lower nozzle element of the sprinkler head nozzle assembly of FIG. 1 in accordance with an embodiment of the present invention;

(5) FIG. 4 illustrates a detailed view of an upper nozzle element of the sprinkler head nozzle assembly of FIG. 1 in accordance with an embodiment of the present invention;

(6) FIG. 5 illustrates a detailed view of the upper nozzle element mounted on the lower nozzle element in accordance with an embodiment of the present invention;

(7) FIG. 5a illustrates a top view of the upper and lower nozzle elements positioned to provide an arc of coverage of 270 degrees;

(8) FIG. 5b illustrates a top view of the upper and lower nozzle elements positioned to provide an arc of coverage of 210 degrees;

(9) FIG. 6 illustrates a bottom view of the distributor of the sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(10) FIG. 7 illustrates a base of the sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(11) FIG. 8 illustrates an arc adjustment ring of the sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(12) FIG. 9 illustrates an intermediate arc drive component of the sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(13) FIG. 10 illustrates a body of the sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(14) FIG. 11 illustrates a flow adjustment element of the sprinkler head nozzle assembly in accordance with an embodiment of the present invention;

(15) FIG. 12 illustrates the flow adjustment element of FIG. 10 mounted in the body of the sprinkler head nozzle assembly of FIG. 11 in an open position; and

(16) FIG. 13 illustrates the flow adjustment element of FIG. 10 mounted in the body of the sprinkler head nozzle assembly of FIG. 11 in a closed position.

DESCRIPTION OF THE EMBODIMENTS

(17) An adjustable arc of coverage sprinkler assembly 1 in accordance with an embodiment of the present invention is shown in cross-section in FIGS. 1-2. In embodiments, the nozzle assembly 2 may be mounted in a sprinkler body 100 including an inlet 101 in fluid communication with a water supply (see FIG. 1A). In embodiments the nozzle assembly 1 may be mounted in the sprinkler body 100 and secured in place via interaction with the threads 102 provided around an outer surface of the top of the sprinkler body 100. In embodiments, the nozzle assembly 1 may be secured to the body 100 via the threads 10a provided on the inner surface of the collar 10. In embodiments, other securing elements may be used in place of the threads if desired. FIG. 1 illustrates an embodiment in which a distributor 2 of the nozzle assembly 1 is in a lowered, closed position. FIG. 2 illustrates the distributor 2 in a raised, open and operating position. In embodiments, the nozzle assembly 1 includes a base 4 with an adjustable arcuate opening A at a top thereof. In embodiments, different upper and lower elements 22, 20 may be provided in the base 4 to provide a full range of arc of coverage. In embodiments, for example, one assembly may provide a range of 90 degrees to 210 degrees, a second assembly may allow for a range between 210 degrees and 270 degrees and a third assembly may be used for an arc of coverage that covers 360 degrees. In embodiments, an arc adjustment ring 3 may be connected to the top of the body or housing 4 and rotates to adjust the length of arcuate opening A, and thus, sets the arc of coverage of the sprinkler in which the nozzle assembly 1 is used. In embodiments, such as in FIGS. 5a-5b, the arcuate opening A may be modified to provide an arc of coverage between 210 degrees and 270 degrees. In embodiments, as noted above, other assemblies, that is, different combinations of upper and lower elements 22, 20, may be provided to provide arcs of coverage over different ranges.

(18) In embodiments, the size (arcuate length) of the arcuate opening A is based on the interaction of the lower stationary valve element 22 and the movable upper valve element 20. FIG. 3 shows a detailed view of the lower valve element 22 configured to provide a 210 degree to 270 degree arc of coverage. In embodiments, the lower valve element 22 includes a cylindrical lower portion 22a with a conical upper portion 22b. In embodiments, the lower portion 22a need not be cylindrical and any other suitable shape may be used. In embodiments, a radial rib 22c extends from the conical upper portion 22b and marks one end of the opening A. A disk-like middle portion 22e may be provided between the upper and lower portions 22b, 22a. A central opening 22d may be provided through the length of the element 22 through which a shaft 30 extends. In embodiments, the disk-like middle portion may include one or more slots 22f formed therein that will allow water to pass therethrough. In the embodiment of FIG. 3, these slots are provided to allow for an arc of coverage of between 210 degrees and 270 degrees.

(19) FIG. 4 shows a detailed view of an embodiment of the upper valve element 20 which is also configured to provide a 210 degree to 270 degree arc of coverage in combination with the lower valve element 22 discussed above. In embodiments, an upper rib 20c may be provided on the top surface 20b thereof and provides the opposite end of the arcuate opening A, opposite the radial rib 22c. In embodiments, the top surface 20b also includes a plurality of engagement ridges 20a positioned around a perimeter of the top surface 20b and generally extending upward. In embodiments, the upper element 20 is substantially cylindrical in shape with an open center 20d through which the top portion 22a of the lower element 22 and the shaft 30 pass. In embodiments, the upper element 20 may be any other suitable shape. In embodiments. The upper element 20 sits on the upper surface of the middle disk-like portion 22e of the lower element 22 as can be seen in FIG. 5, for example. In embodiments, water flows between an outer surface of the lower element 22 and inner surface of the upper element 20 between the rib 22c and the rib 20c through the arcuate opening A. In embodiments, rotation of the upper element 20 relative to the stationary lower element 22 adjusts the position of the rib 20c relative to the rib 22c to change the arcuate length of the opening A and the arc of coverage provided by the assembly 1. In embodiments, varying the arcuate length of the opening A will change the arc of coverage provided by the nozzle assembly 1.

(20) FIG. 5 illustrates a detailed view of the upper element 20 mounted on the lower element 22. FIG. 5a shows a top view of the upper element 20 and lower element 22 where the arcuate opening A is set to provide an arc of coverage of 270 degrees. As noted above, the upper element 20 and lower element 22 may be provided in different combinations to vary the arcuate length of the opening A. FIG. 5b shows a top view of upper and lower elements 20, 22 with the opening A set for an arc of coverage of 210 degrees. As can be seen in FIGS. 5a and 5b, as the upper element 20 rotates relative to the element 22 which remains stationary, the opening A changes in size to provide an arc of coverage between 270 degrees and 210 degrees. In embodiments, the upper valve element 20 is rotated via the arc adjustment ring 3 which is accessible from an exterior of the nozzle assembly 1. In embodiments, the arc adjustment ring 3 may be operatively connected to an interim arc adjustment element 5 such that rotation of the ring 3 rotates the interim arc adjustment element 5. In embodiments, as can be seen in FIG. 8, the arc adjustment ring 3 may include two inwardly extending protrusions 3a extending from an inner surface thereof. While FIG. 8 illustrates two protrusions 3a, fewer or more protrusions may be used. In embodiments, the protrusions 3a are received in slots 5a (see FIG. 9, for example) formed in a top lip of the interim arc adjustment element 5 such that rotation of the ring 3 will also rotate the element 5. In embodiments, fewer or more slots 5a may be provided for interaction with the protrusions 3a. In embodiments, the interim arc adjustment element 5 preferably includes a plurality of notches 5b formed around an inner opening thereof. In embodiments, the notches 5b may receive the engagement ridges 20a formed on the upper element 20 such that the upper element 20 will rotate with the interim arc adjustment element 5 to adjust the arcuate length of the opening A.

(21) In embodiments, a flow control ring 9 may be provided upstream of the upper and lower elements 20, 22 and is adjustable to adjust a flow of water thereto. In embodiments, as indicated in FIG. 11, for example, the flow control ring 9 may include a bottom element with a plurality of flow openings 9a formed therein. In embodiments, the base 4 includes a body element 8 extending from a bottom portion thereof that receives the lower portion of the control ring 9. The base 8 may include a plurality of body flow openings 8a. The flow control ring 9 may be rotated to bring the flow openings 9a into alignment with the body flow openings 8a to allow substantially free flow of water through the openings 8a, 9a (see FIG. 12, for example). In embodiments, the flow control ring 9 may also be rotated in the opposite direction to move the openings 9a out of alignment with the openings 8a to reduce the flow of water the upper and lower nozzle elements. FIG. 12 illustrates an exemplary embodiment in which the openings 9a and 8a are aligned and FIG. 13 illustrates an exemplary embodiment in which the openings 9a and 8a and out of alignment and the flow of water is shut off.

(22) In embodiments, the base 8 is held stationary via connection to the body 4. In embodiments, the body 4 may include a plurality of securing slots 4a formed in a lower internal flange 4b thereof (see FIG. 7). In embodiments, the base element 8 may include a plurality of stakes 8b that extent up from a top surface thereof through the securing slots 4a such that the base 8 is held in place as the ring 9 rotates.

(23) In embodiments, the shaft 30 extends through the elements 20 and 22, the body 4, the base 8 and the flow control ring 9. In embodiments, the distributor 2 may be mounted on a top of the shaft 30 and both are movable axially from the closed position of FIG. 1 to the open position of FIG. 2. In embodiments, the shaft 30 and the distributor 2 may be biased into the closed position via biasing element 30a. In embodiments, a stopper 30b may be provided at a bottom of the shaft 30 to limit upward movement of the shaft 30 and distributor 2. In embodiments, the end of the shaft 30 and the stopper 30b may be mounted in a filter basket 35. In embodiments, the filter basket 35 may not be used.

(24) In operation, water passes through the filter basket 35 (when provided) and through the openings 9a, 8a, which may or may not be used control flow based on their alignment. Water then flows upward between the lower element 20 and the upper element 22, along the conical outer surface of the top portion 22b of the lower element 22 through arcuate opening A. The water the projects upward onto a bottom surface of the distributor 2. In embodiments, the force of the water lifts the distributor 2 and the shaft 30 axially upward and into the opening position of FIG. 2. As noted above, the stopper 30a may limit upward movement of the distributor and shaft. The water striking the distributor 2 passes through the channels 2a and flows through them from the central portion of the distributor 2 to the outer periphery where the water continues to flow as a plurality of streams from the assembly 1. The channels 2a are curved and shaped to direct water out of the assembly 1 in the plurality of streams. In embodiments, the water imparts rotation to the distributor 2 as it flows through the curved channels 2a. When the water is turned off, the biasing element 30a pulls the distributor 2 back into the closed position of FIG. 1. In this closed position, the distributor 2 is protected from mechanical damage and clogs.

(25) In embodiments, the distributor 2 may include a viscous braking chamber 2b to control the speed of rotation of the distributor as it rotates. A bearing 30b may be provided at a bottom of the chamber through which the shaft 30 passes to allow the distributor 2 to rotate relative to the rod. A stator 30c is preferably provided above the bearing 30b and secured to the rod such that it remains stationary with the rod as the distributor 2 rotates. A cap 2c may be provided on top of the distributor 2 defining a top of the chamber 2b. In embodiments, the chamber 2b includes or is filled with a viscous fluid. In embodiments, as the distributor 2 rotates, viscous dampening occurs between the stator 30c and the walls of the chamber 2b which limits the speed of rotation. The faster the distributor 2 spins, the higher the viscous dampening force limits the speed of rotation of the distributor 2.

(26) In embodiments, the conical top portion 22b of the lower nozzle element 22 is shaped to optimize the flow of water to the distributor 2. In embodiments, the conical shape of the upper portion 22b of the lower nozzle element 22 provides for a conical flow of water to the distributor 2 which may be optimized such that the water strikes the distributor in a preferred area and at a preferred angle to maximize flow and a smooth output in the streams. In embodiments, it is preferable that the water stream strike the bottom surface of the distributor 2 in the area that is about 20-30% of the length of the channel 2a away from the inner or bottom end of the channel at an angle of about 10 to 15 degrees.

(27) The sprinkler head assembly 1 of the present disclosure provides adjustment of the arc of coverage and flow control while also providing a conical nozzle to optimize the flow of water provided to the distributor 2. Further, only the distributor 2 and shaft 30 rise up and down such that the assembly 1 is simpler and less expensive to produce than conventional assemblies. The sprinkler nozzle head assembly 1 thus provides for reliable operation and allows for water conservation.