Many popular rotors or irrigation sprinklers in the market today require the use of a screwdriver to set the watering arc. For example, some rotors have an arc adjust shaft accessible from a top of the rotor that, when turned, rotates an arc adjust gear keyed to an adjustable stop. The rotors typically have a fixed left stop and an adjustable right stop. Setting the watering arc can be a slow process of repeated screwdriver arc adjustments and arc setting checks before the desired arc setting is achieved. Typically, rotors of this type can be adjusted to spray within a watering arc of about 40° to 350°.
In the previously described designs, a bull gear is keyed to the nozzle base, allowing the nozzle base to be manually rotated, typically referred to as fast-forwarding, to quickly see the arc setting. This can be done both wet (under pressure) and dry. The stop at each edge is felt tactically by the click of the trip arm and the hard stop as the drive gear engages against the direction of fast-forwarding. Rather than fast-forwarding, an alternate method to determine the watering arc is to watch the unit rotate and trip on each side. This is not ideal because rotors do not typically rotate very quickly.
Fast-forwarding must be actuated towards the direction of drive engagement, both wet and dry. Attempting to back-drive the mechanism will likely break gears if a clutch is not present to take the abuse. When the nozzle base is fast-forwarded with the direction of the drive, the trip mechanism ratchets and prevents damage to the gears.
The present invention is directed to a rotor or sprinkler that allows its watering arc to be rotated, increased, or decreased by user-rotation of the sprinkler's rotating nozzle base.
Specifically, if the nozzle base is rotated in a first direction so as to pass the trip stop on that side, the entire watering arc is rotated to cover a different area of turf around the sprinkler. If the user wishes to increase the angle or size of the watering arc, the nozzle base can be rotated in a second direction, beyond the trip stop. Finally, the watering arc can be reduced by “fast forwarding” the nozzle base in a first direction without tripping the trip stop, then rotating the nozzle base in a second direction.
These and other aspects, features and advantages of which embodiments of the invention are capable of will be apparent and elucidated from the following description of embodiments of the present invention, reference being made to the accompanying drawings, in which
Specific embodiments of the invention will now be described with reference to the accompanying drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. The terminology used in the detailed description of the embodiments illustrated in the accompanying drawings is not intended to be limiting of the invention. In the drawings, like numbers refer to like elements.
In one embodiment, the present invention is directed to a rotor or sprinkler 100 that allows its watering arc 102 to be fully adjusted by user-rotation of the sprinkler's rotating nozzle base 104.
Specifically, if the nozzle base 104 is rotated in a first direction so as to pass the trip stop on that side, the entire watering arc 102 is rotated to cover a different area of turf around the sprinkler 100. However, movement in this first rotational direction maintains the overall angle or arc area of the watering arc 102 between the left edge 102B and right edge 102A. For example,
If the user wishes to increase the angle or size of the watering arc 102, the nozzle base 104 can be rotated in a second direction. For example,
Finally, the watering arc 102 can also be reduced in size/angle. For example, in
In this regard, a user can install a sprinkler 100, then immediately rotate or “fast-forward” the nozzle base 104 clockwise (or a first direction) to determine where the “fixed” right edge 102A of the watering arc 102 should be located, then can rotate the nozzle base 104 counter clockwise to determine the left edge 102B of the watering arc 104 is located (i.e., the overall size of the watering arc 102 relative to the right edge 102A).
The nozzle base 104 generally refers to the top housing of the riser portion 106 in which the nozzle 105 is located. While the term nozzle base is used in this specification, this item can also be referred to as a nozzle housing, nozzle enclosure, rotating riser portion, or by other, similar terms.
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The pivot angle of the drive gear assembly 122 is controlled by the trip arm 118. Specifically, the trip arm 118 can be rotated between a right trip stop 124A and a left trip stop 124B. This rotation or movement of the trip arm 118 is assisted by two springs 135 connected to the trip arm 118 and to spring aperture 137 (note: springs are illustrated as being disconnected from apertures 137 for clarity purposes). Portions of the trip arm 118 contact the drive gear assembly 122, such that when the trip arm 118 is in a first position, gear 122D extends radially outwards, and when the trip arm 118 is in a second position, gear 122C extends radially outwards.
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The inner geared wall 126C of the clutch member 126 is located over a tubular portion 104A of the nozzle base 104, engaging the outer geared portion 104B. Hence, as the bull gear 118 rotates, it causes the clutch member 126 to similarly rotate, which in turn rotates the geared portion 104B of the nozzle base 104, resulting in rotational movement of the nozzle base 104 relative to the remaining portions of the sprinkler 100.
The trip arm 118 can be moved between its two positions by rotation of a bull gear trip dog 120A located on the bull gear 120 (see
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As previously described with regard to
Specifically, as the user rotates the nozzle base 104 clockwise, the adjustable stop trip dog 116B contacts the trip arm 118 and therefore is unable to be rotated any further. Similarly, since the adjustable stop trip dog 116B “flipped” the trip arm 118, the drive gear assembly 122 is oriented such that it engages the geared portion 120B of the bull gear 120 and attempts to rotate the bull gear 120 in a direction opposite the clockwise rotation of the user. In other words, the bull gear 120 is effectively maintained in place by the direction of rotation of the drive gear assembly 122, while the nozzle base 104 and clutch member 126 rotate relative to the trip dogs 116B, 120A.
Despite the fixed positions of both the bull gear 120 and adjustable stop member 116, the user can further rotate the nozzle base 104 in a clockwise direction since that rotation overcomes the force of the fingers 126A of the clutch member 126. Hence, in the clockwise rotational direction, the clutch member 126 allows the nozzle base 104 to rotate past the trip stop, changing the relative position of the nozzle 105 to the bull gear 120 and adjustable stop member 116. Since the adjustment shaft 112 rotates with the nozzle base 104, it further rotates within the nozzle base 104 to account for its movement around adjustment gear 114.
As previously described with regard to
Specifically, as the nozzle base 104 is rotated in a counter clockwise direction, the adjustable stop member 116 is also rotated with the nozzle base 104. This movement occurs since the adjustment shaft 112 and the arc adjustment gear 114 engage the adjustable stop member 116. The arc adjustment shaft 112 is frictionally engaged with the nozzle base 104 via an o-ring 111 (
As the nozzle base 104 is rotated or “fast forwarded” through the watering arc 102, the bull gear trip dog 120A contacts and “flips” the trip arm 118, thereby reversing the direction of rotation that the drive gear assembly 122 exerts on the bull gear 120. In this respect, the drive gear assembly 122 maintains the rotational position of the bull gear 120. Since the bull gear 120 is maintained in place, further counter clockwise rotation of the nozzle base 104 results in enough force to overcome the engagement of the clutch member 126 with the geared region 120B of the bull gear 120. Hence, the adjustable stop trip dog 116B moves away from the bull gear trip dog 120A, increasing the watering arc 102.
As previously described with regard to
Specifically, the user initially rotates the nozzle base 104 in the same direction that the gear assembly 122 attempts to rotate the bull gear 120 (i.e., “fast forwarding”), and therefore the clutch member 126 maintains its engagement with the bull gear 120. Since the user then reverses the direction of rotation of the nozzle base 104 without tripping the trip arm 118, the reversed rotational direction is opposite of the direction that the gear assembly 122 is rotating the bull gear 120. Hence, the clutch member 126 disengages with the bull gear 120 and the adjustable trip stop member 116 is rotated towards the trip arm 118, thereby reducing the size of the watering arc 102.
In this respect, the user can adjust the watering arc 102 by rotating the nozzle base 104 and without the need for an adjustment tool.
While the embodiment in these figures has been described such that rotating the nozzle base 104 in a clockwise or counter clockwise direction performs a certain adjustment action, it should be understood that the sprinkler 100 could also be configured to perform the same adjustment functions when turned in opposite directions. In other words, the sprinkler 100 can be configured to perform its arc adjustment functions in either direction.
The terms arc stop, trip stop, and similar terms are used in this specification and designate one of two locations in which the nozzle base 104 changes rotational direction. In this regard, the arc or trip stop locations are determined by the position of the adjustable stop trip dog 116B and the bull gear trip dog 120A within the sprinkler 100.
While the hand-adjustments of the present sprinkler 100 can be performed while the sprinkler 100 is in operation (i.e., spraying water), it should also be understood that they can be performed while water to the sprinkler 100 is turned off (i.e., dry).
Although the invention has been described in terms of particular embodiments and applications, one of ordinary skill in the art, in light of this teaching, can generate additional embodiments and modifications without departing from the spirit of or exceeding the scope of the claimed invention. Accordingly, it is to be understood that the drawings and descriptions herein are proffered by way of example to facilitate comprehension of the invention and should not be construed to limit the scope thereof.
This application claims priority to U.S. Provisional Application Ser. No. 61/865,897 filed Aug. 14, 2013 entitled Sprinkler Arc Adjustment Mechanism, which is hereby incorporated herein by reference in its entirety.
Number | Name | Date | Kind |
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4901924 | Kah, Jr. | Feb 1990 | A |
5383600 | Verbera | Jan 1995 | A |
5685486 | Spenser | Nov 1997 | A |
7261247 | Yeh et al. | Aug 2007 | B2 |
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Number | Date | Country | |
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20150048174 A1 | Feb 2015 | US |
Number | Date | Country | |
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61865897 | Aug 2013 | US |