1. Field of the Disclosure
The present disclosure relates to a sprinkler head nozzle assembly that includes a rotating deflector and provisions for adjustment of the arc of coverage, stream elevation angle, range and flow rate. The assembly is suitable for use in both gear driven and viscous damped self driven rotating deflectors.
2. Related Art
Prior art sprinkler nozzle assemblies have been provided that allow for arc of coverage adjustment such as U.S. Pat. No. 5,148,990 issued the inventor of the present application, however, this reference does not provide for easy adjustment of range from the outside of the assembly.
Other references describe partial arc of coverage adjustment and flow control with a center shaft and small screws. However, this type of flow control is relatively inconvenient. These references include U.S. Pat. Nos. 6,651,905, 6,736,332 4,986,474, 5,058,806 and 4,898,332.
However, the reference require the use of complex axially movable adjustment mechanisms which are difficult to manufacture and assemble. Further, none of these references disclose interlinking arc of coverage adjustment with proportional upstream throttling to maintain a constant range of coverage as the arc is changed.
Accordingly, it would be beneficial to provide a sprinkler nozzle assembly that avoids these problems.
A sprinkler head nozzle assembly in accordance with an embodiment of the present application includes a nozzle housing with an inlet for pressurized water and an outlet downstream of the inlet, a rotatable arc of coverage adjustment ring mounted on the housing such that rotation of the arc of coverage adjustment ring increases or decreases an arcuate water outlet, or exit, opening, or orifice, to increase or decrease the arc of coverage of water around the sprinkler and a range adjustment ring mounted on the nozzle housing for adjusting an upstream flow area in the nozzle housing to reduce a pressure of water provided to the arcuate water outlet opening such that the discharge velocity, and thus, the range of coverage of the water and flow rate are changed in accordance with the arc of coverage.
A sprinkler head nozzle assembly in accordance with an embodiment of the present application includes a nozzle housing including an inlet for pressurize water and an outlet downstream of the inlet, a rotating arc adjustment ring mounted on the housing such that rotation of the arc adjustment ring extends and reduces an arcuate exit opening to set an arc of coverage of the sprinkler head nozzle assembly, a rotating range adjustment ring mounted on the housing upstream of the arc adjustment ring such that rotation of the range adjustment ring increased and decreases a downstream flow area to control flow of water to the arcuate exit opening and a rotating deflector, mounted on a central shaft extending through the arc adjustment ring, the range adjustment ring and the nozzle housing operable to deflect a flow of water extending through the flow area and the arcuate exit opening out of the nozzle assembly, wherein the range adjustment ring is operationally linked to the arc adjustment ring such that the flow area is adjusted with the arcuate exit opening to maintain substantially the same range of coverage of the water deflected out of the nozzle assembly as the arc of coverage is adjusted.
A sprinkler head assembly in accordance with another embodiment of the present application includes a nozzle housing including an inlet for pressurize water and an outlet downstream of the inlet, a rotating arc adjustment ring mounted on the housing such that rotation of the arc adjustment ring extends and reduces an arcuate exit opening to set an arc of coverage of the sprinkler head nozzle assembly, a rotating range adjustment ring mounted on the housing upstream of the arc adjustment ring such that rotation of the range adjustment ring increases and decreases a downstream flow area to control flow of water to the arcuate exit opening; and a rotating deflector, mounted on a central shaft extending through the arc adjustment ring, the range adjustment ring and the nozzle housing operable to deflect a flow of water extending through the flow area and the arcuate exit opening out of the nozzle assembly, wherein the arcuate exit opening is formed by interaction of a first axially stepped spiral surface of the arc adjustment ring and a second axially stepped spiral surface of the nozzle housing.
A sprinkler nozzle assembly according to another embodiment of the present application includes a nozzle housing including an inlet for pressurize water and an outlet downstream of the inlet, a self driven rotary deflector mounted for rotation on a center shaft that passes through the nozzle housing and a viscous dampening assembly wherein a clearance between a rotor connected to the center shaft and an inner surface of the assembly housing is adjustable to adjust a speed of rotation of the deflector.
The present application provides for nozzle configurations that use both arcuate slot members interacting with closure members and axially stepped interacting spirals that rotate relative to each other to provide a fully adjustable arcuate length outlet opening for discharging water onto a deflector, whether rotatable or stationary. That is, the nozzle assembly of the present disclosure is suitable for use in fixed spray nozzle type sprinklers as well as rotary deflector stream rotors.
The arc and range control elements of the present application are preferably mounted on the nozzle housing and are shown with rotary viscous damping provided by an upstream housing mounted assembly as well as with viscous damping provided in the self driven rotary deflector itself.
The range adjustment ring may be functionally coupled to the rotatable arc of coverage adjustment ring so that as the arc of coverage adjustment ring is rotated, the range adjustment ring rotates with it unless one of these rings is separately held and their relative rotational position is changed to establish a different flow rate and upstream restriction which is varied proportionally to the arcuate slot opening as the arc of coverage is set to maintain constant range of coverage as the arc of coverage changes.
Thus, for any arc of coverage, once the rotational relationship of these two rings is set to provide a desired range of coverage outwardly from the sprinkler, this range of coverage is maintained for whatever different arc of coverage is now set due to the upstream proportional throttling that occurs as the arc set ring is rotated which also rotates the frictionally coupled range adjustment ring.
Also disclosed herein is a simple non-axially moving partial arc of coverage arcuate slot opening valve configuration settable, for example, from 85°-185° of coverage by a circumferentially mounted ring on the sprinkler nozzle assembly body.
The components of this arcuate length flow settable valve are preferably snapped together during assembly to provide an adjustable arc of coverage range: i.e. of 85° to 185°, or full circle and a range of coverage: i.e. 8 to 25 ft., for example. This allows for a low cost sprinkler with arc and range of coverage control.
Other features and advantages of the present invention will become apparent from the following description of the invention which refers to the accompanying drawings.
A partially adjustable arc of coverage sprinkler head nozzle assembly 1, in accordance with an embodiment of the present application is shown in perspective view in
The arc adjustment ring 3 and the range adjustment ring 5 may also be snapped together around their outside circumference by the matching steps and notches (3c, 4c, 5b and 5c) provided on the circumferences of these rings, as shown in
The slot member 20 is rotationally fixed in the nozzle housing 4 such that slot 22 in slot member 20 is opened and closed by rotation of the arc adjustment ring 3, which moves the opening 3A into an open relationship with slot 22 as shown on the left hand side in
The arc adjustment ring 3 is preferably frictionally coupled to the range adjustment ring 5 so that as the arc adjustment ring is rotationally set to uncover the desired arcuate length of slot 22, an upstream flow area is increased or decreased to provide upstream flow restriction, to adjust the range of coverage. That is, as the arc of coverage is increased by rotation of the arc adjustment ring 3, the upstream flow area is preferably increased to increase the flow of water to match the same range of coverage of water over the increased arc of coverage. Similarly, as the arc of coverage decreases, the upstream flow area is decreased so that the range of coverage of water remains the same for the smaller arc of coverage.
As shown in
More specifically, as shown at
In this manner, the rings 3 and 5 are retained axially around their outer circumference, but are free to be rotated without restriction unless stops are desired. In a preferred embodiment, the range adjustment ring 5 may also be rotated to a fully shut off position if desired. That is, the range adjustment ring may be rotated such that the flow area is reduced to essentially 0, if desired. The slot member 20 is preferably snapped into the nozzle housing 4 at 40 as is illustrated in
The relative position of the range adjustment ring 5 to the nozzle housing 4 is used to adjust the flow of water through the nozzle assembly 1. Specifically, a radially stepped opening 5a is formed through the range adjustment ring 5 and interacts with a matching radially stepped opening 4a in the nozzle housing 4. The opening 5a has a uniformly increasing radial distance for each degree of rotation such that rotation of the ring 5 increases or decreases the flow area proportionally to maintain a desired flow to arc of coverage ratio. The flow area may be uniformly opened or closed as shown in
The radially spaced opening 5a formed in the range adjustment ring 5 is illustrated in
A viscous damping assembly 10 is preferably provided in a lower portion of the assembly 1 to control the speed of rotation of a rotating deflector 2. As noted above, the deflector 2 is mounted on the rotating shaft 15. A rotor assembly 16 is connected to the shaft 15 and viscous damping is provided based on the spacing between the rotor 16 and an inner surface 13 of the assembly 10. The smaller the space, the more viscous damping is provided.
A hex shaped nut is preferably rotationally tied to the inside opening 2A of the deflector 2. As the deflector 2 rotates, the shaft 15 which is coupled to the nut 31 also rotates. The shaft extends down through the slot member 20 and fit into lower viscous damping assembly 10 of nozzle housing 4 at 40.
Specifically, a tapper rotor 16 that preferably has a thin light spring rating, i.e. ½ pound per 1/16 of an inch of compression wave washer 70 that changes to allow the running clearance between the rotor 16 and the inside wall 13 of the housing to be reduced as the upward pressure increases on the deflector 2 and pulls up the shaft 15. This provides rotor speed compensation for changes of flow rate and slow rate changes for range changes discharging onto the rotating self driven deflector 2.
When the assembly 1 is first provided with water, viscous damping is at a minimum. Viscous drag is essentially directly proportional to the clearance between the stationary surface 13 and the rotor 16. Since the walls of the damping chamber are tapered, the clearance between the wall and the rotor is increased as the washer moves the rotor downward for less viscous rotational resistance. When the pressure directed against the deflector 2 increases, the load on the deflector upward and this axial load are transferred to the viscous damping rotor 16 it compresses the washer and causes the clearance to be reduced and the resistance to increase. As a result, it is easier to limit speed despite the increased pressure of the water and there is less viscous rotational resistance when the sprinkler is first starting to the assembly to overcome any static friction.
The assembly 1 provides only partial arc of coverage adjustment in that the arc of coverage is only adjustable based on the length of the slot 22 and its closed off area which hides the closure part of the arc set ring 3 as at 3A.
An alternative embodiment of an adjustable nozzle assembly 1′ is illustrated in
In the alternative assembly 1″41 of
In the deflector 21″″, as shown in
An adjustable viscous damping stator 94 is screwed down onto the thread on shaft 15 above the rotating deflector retention nut 100. Turning the adjustable stator 94 via slot 98 about its threads on the shaft 15 changes the viscous damping clearance 110 during operation. This allows for adjusting rotational speed of the self driven deflector 2″″ by tangential components of the discharge stream.
In the assembly 100, the range adjustment ring 5 has slots 20 as can be seen in
The range adjustment ring 5 is shown rotated relative to the nozzle housing so that the upstream flow opening is at a minimum in
The posts 21 extending upward from the top of the nozzle housing 4 in
The flow entering to the discharge, or exit, slot is shown as 22C in
In
In
The flow area to the slot 95 of
In addition, a shut off portion is indicated at 97 of
The stationary end closure 92 includes a standing rib shown at 92 in
Further, the upstream flow area B is adjusted to control flow, and thus, the range of coverage. The size of the opening B is increased and decreased to vary the flow proportionally to the arc of coverage set by the opening A to maintain a constant range once the axial relationship between upstream valving element 303c of the flow adjustment ring 300 and the flow insert 3070 is set. The insert 3070 is illustrated in more detail in
Specifically, the pitch of threads 303e, 300a, 400a and 300b are all the same, so that as the arc adjustment ring 303 is held rotationally fixed and the range adjustment ring 300 is rotated to change the upstream flow area B, the range adjustment ring is unscrewed from thread 303e and is moved for a greater range of coverage; i.e. the flow area B would be further opened, then the threads 300b of the range control ring 300 are screwed down into the housing 400 with threads 400a maintaining the same total stack height to keep the spiral adjustable set valving surface of 3022 in contact as shown on the left and open at A as shown on the right and maintain the arc of coverage.
One additional feature of the assembly l″ of
The deflector 302 is preferably made of an elastomeric material where the outer circumference can be deflected downward by tightening the nut 3040 in the center of the deflector shaft 3015 to modify the outer circumference 302c to deflect down, and thus, reduce the stream exit angle which can also be used to change the range of coverage of the assembly.
One of the benefits provided aside from rotor speed compensation for arc of coverage and range throttle pressure reduction to the nozzle discharge onto the rotating self driven deflector is that when a hex shaped nut is rotationally tied to the inside of opening 2a of the rotating deflector 2, its matching hex hole 21 shape and the nut tightens onto step 15a of the rotationally viscous damped shaft 15.
The rotating deflector shaft 15 extends down through the clearance holes in the center of arc quadrant 20 and its lower snap shaft and into a separate viscous damped rotor housing assembly 10 that is inserted in the nozzle house 4 at 41 . After it has been separately assembled, it is secured in place by a sonic weld and press fit at 41 to the cylindrical member 29 (see
A perspective view of the assembly in
The sprinkler nozzle assembly of the present application thus provides for arc of coverage and range of coverage adjustment from the exterior of the assembly. This is provided by interaction between both radially stepped openings and axially stepped openings that are modified to increase and decrease the arcuate length of both outlet openings which controls arc of coverage and and upstream flow areas which controls range of coverage. Viscous damping may be provided in the nozzle housing or in the deflector itself. In addition, the nozzle assemblies of the present application may be used in conjunction with water turbines in place of viscous damping assemblies.
In a preferred embodiment, the range adjustment element is operably connected to the arc adjustment element such that a desired range of coverage is maintained as the arc of coverage is changed. Specifically, an upstream flow area is increased and decreased as appropriate to provide a substantially constant range of coverage despite changes in the arc of coverage.
Thus, for any particular arc of coverage, once the range of coverage is set, it will be maintained even as the arc of coverage is adjusted. The range control element preferably provides upstream proportional throttling of the flow area to adjust the range as the arc of coverage is adjusted.
Limited arc of coverage control is provided over an arc range of approximately 85 degrees to 185 degrees when radially stepped openings alone are used. In this case the adjustment components, such as the ring 3 and 5, for example, are snap fit together and to the housing 4, for example, to provide for easy manufacturing and assembly. When axially stepped openings are used, a full arc of coverage from 0 to 360 degrees may be provided.
In one embodiment flow control may be provided by inhibiting flow through a plurality of small openings as indicated in
Although the present invention has been described in relation to particular embodiments thereof, many other variations and modifications and other uses will become apparent to those skilled in the art.
The present application claims benefit of and priority to U.S. Provisional Patent Application Ser. No. 61/018,833 filed Jan. 3, 2008 entitled SPRINKLER HEAD NOZZLE ASSEMBLY WITH ARC COVERAGE SETTING RING AND RANGE OF COVERAGE SETTING RING and U.S. Provisional Patent Application Ser. No. 61/018,847 filed Jan. 3, 2008 entitled ARC AND RANGE OF COVERAGE ADJUSTABLE STREAM ROTOR SPRINKLER, the entire content of each of which is hereby incorporated by reference herein. The present application is also related to U.S. Provisional Patent Application Ser. No. 60/912,836, filed Apr. 19, 2007, entitled ADJUSTABLE ARC FLOW RATE AND STREAM ANGLE VISCOUS DAMPED STREAM ROTOR, U.S. Provisional Patent Application Ser. No. 60/938,944, filed May 18, 2007, entitled LOW FLOW RATE FULLY ADJUSTABLE SPRINKLER NOZZLES and U.S. patent application Ser. No. 11/947,571, filed Nov. 29, 2007, entitled SPRINKLER HEAD NOZZLE ASSEMBLY WITH ADJUSTABLE ARC, FLOW RATE AND STREAM ANGLE, the entire content of each of which is hereby incorporated by reference herein.
Number | Date | Country | |
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61018847 | Jan 2008 | US | |
61018833 | Jan 2008 | US |