This relates to irrigation system components, and more specifically, to irrigation rotor sprinklers.
Pop-up irrigation rotor sprinklers are known in the art and are especially useful where it is desired that they be placed in the ground so that they are at ground level when not in use. In a typical pop-up rotor sprinkler, a tubular riser is mounted within a generally cylindrical upright sprinkler housing or case having an open upper end. A spray head carrying one or more spray nozzles is mounted at an upper end of the riser and supports a housing cap or cover to close the housing when the sprinkler is not in operation.
In a normal inoperative position, the spray head and riser are spring-retracted into the sprinkler case so that they are below ground level. However, when water under pressure is supplied to the sprinkler case, the riser is extended upwardly to shift the spray head to an elevated spraying position spaced above the sprinkler case and the ground. The water under pressure flows through a vertically oriented passage in the riser to the spray head which includes one or more appropriately shaped spray nozzles for projecting one or more streams of water radially outwardly over a surrounding terrain area and vegetation.
In many pop-up sprinklers, a rotary drive mechanism is provided within the sprinkler case for rotatably driving the spray head through continuous full circle revolutions, or alternately, back and forth within a predetermined part-circle path, to sweep the projected water stream over a selected target terrain area. In one known design, the rotary drive mechanism comprises a water-driven turbine which is driven by the pressurized water supplied to the sprinkler case. This turbine rotatably drives a speed reduction gear drive transmission coupled in turn to the rotary mounted spray head. In addition, adjustable means are normally provided to cause spay head rotation to reverse upon reaching a predetermined, part-circle path of motion, or to achieve continuous, full-circle rotation, if desired.
While these sprinklers generally provide reliable service, from time to time they can malfunction due to the wearing of parts or to debris entering the units thereby obstructing or clogging their interior components. Malfunctions can include a failure of the riser to extend upwardly, or a failure to rotate at the proper speed or direction. It is therefore necessary for an operator to directly observe the sprinklers when they are in operation to ensure that they are in proper working order.
For irrigation systems installed in large facilities, such as for example, golf courses, this direct observation by a user often requires that he or she take the time to travel throughout the entire facility to observe the operation of a plurality of sprinklers. What would be desirable, therefore, is an improved irrigation device that provides some automatic indication and verification of proper sprinkler operation.
Embodiments of the invention provide a new and improved rotary sprinkler that includes a relatively simple, inexpensive, yet reliable assembly for automatically and accurately indicating the operating condition of the sprinkler and which can provide the information to a central control station for alerting an operator of any potential sprinkler irrigation problems. More specifically, embodiments of the invention employ a Hall-effect sensor that is adapted to detect the position or rotation of the sprinkler in order to provide a signal indicative of the sprinkler condition and rate of rotation. This signal can be transmitted, either wirelessly or via conductors, to a central control station for automatic response or observation by the system operator.
According to one embodiment of the invention, a sprinkler nozzle assembly is rotatable and has one or more magnets coupled or connected to the assembly so that they synchronously rotate with it. A sensor unit is mounted adjacent to the magnets and provides electrical signals in response to the magnetic fields produced by the rotating magnets. These electrical signals are used to provide information as to both the direction of rotation and the speed of rotation of the nozzle assembly. This information is transmitted either wirelessly or via wires to a computer or monitor at a central location where a user can easily monitor the operation of a plurality of units.
In one aspect, a first magnet is connected to the nozzle assembly and adapted to produce a first magnetic field, wherein the first magnet rotates in response to the rotation of the nozzle assembly. A sensor unit comprising a Hall-effect sensor is mounted adjacent to the nozzle assembly for detecting the first magnetic field when the nozzle assembly is rotating.
In another aspect, a second magnet is connected to the nozzle assembly and adapted to produce a second magnetic field that rotates in response to the rotation of the nozzle assembly. The sensor unit comprises two Hall-effect sensors, and detects the second magnetic field when the nozzle assembly is rotating. Additionally the sensor unit detects the direction of rotation and the speed of rotation of the nozzle assembly.
There are additional aspects to the present inventions. It should therefore be understood that the preceding is merely a brief summary of several embodiments and aspects, and that additional embodiments and aspects of the present inventions are referenced below. It should further be understood that numerous changes to the disclosed embodiments can be made without departing from the spirit or scope of the inventions. The preceding summary therefore is not meant to limit the scope of the inventions. Rather, the scope of the inventions is to be determined by appended claims and their equivalents.
These and/or other aspects and advantages of the present invention will become apparent and more readily appreciated from the following description of the preferred embodiments, taken in conjunction with the accompanying drawings of which:
a is a top plan view of a rotating ring of the irrigation sprinkler of
b is a perspective view of the rotating ring of
Reference will now be made in detail to exemplary embodiments of the present invention, which are illustrated in the accompanying drawings, and wherein like reference numerals refer to like elements throughout. It is understood that other embodiments may be utilized and structural and operational changes may be made without departing from the scope of the present invention.
According to one embodiment of the invention, an irrigation sprinkler is disclosed that includes a rotatable nozzle assembly with a plurality of magnets coupled or connected to the nozzle assembly so that they synchronously rotate with it. A stationary sensor unit is mounted adjacent to the magnets and provides electrical signals in response to the magnetic fields produced by the rotating magnets.
The sensor unit includes two Hall-effect sensors located in one housing. When a magnetic field associated with one magnet sweeps past one of the Hall-effect sensors, and then sweeps past the other Hall-effect sensor, the direction of rotation can be determined. Moreover, when a magnetic field associated with one magnet sweeps past one Hall-effect sensor, and then a second magnetic field associated with a second magnet sweeps past the same Hall-effect sensor, the time that elapses between these events can be measured and a speed of rotation calculated.
Thus by generating electric signals indicative of nozzle assembly direction and speed of rotation, the sensor unit and associated electronics can provide a signal indicative of the direction and speed of rotation for each irrigation sprinkler which signals can then be transmitted, either wirelessly or via wires, to a computer or monitor or other electronic device having a processor located remotely from each irrigation sprinkler. This enables a user who is in a central location to monitor the operation of many, widely-dispersed irrigation sprinklers without having to travel in the field for monitoring purposes.
A bearing guide 18, a lower snap ring 20, a rotating ring 22, and an upper snap ring 24 are each adapted to surround the nozzle base 16 and fit within the case 12. As will be explained in further detail below, the bearing guide 18, the lower snap ring 20, and the upper snap ring 24 are adapted to rigidly seat within the case 12, whereas the rotating ring 22 is adapted to “float” within the case 12.
A nozzle housing 26 mates with the nozzle base 16 (thereby forming a nozzle assembly), and includes vertical nozzle housing grooves 40 formed on the exterior surface of the nozzle housing 26 that are aligned with the grooves 36 in the nozzle base 16. In response to pressurized water flowing through the irrigation sprinkler 10, the nozzle base 16 and nozzle housing 26 rotate with respect to the riser 14 and the case 12. A rubber collar 28 is seated at the top of the case 12 and surrounds the nozzle housing 26. This serves to prevent debris from entering the case assembly. A sensor unit 30 is attached to the exterior of the case 12, and located near its upper portion.
While the embodiment of
The lower snap ring 20 is rigidly seated in the case interior 39 and is located to contact or abut an upper surface 44 of the bearing guide 18 thereby maintaining the bearing guide 18 in position so that it may seal the compartment below. The rotating ring 22 is adapted to fit within the case 12 and surround the nozzle base 16 and tubular upper portion 32 of the riser 14. The rotating ring 22 is constructed of plastic and sits on a seating surface or flange 46 of the interior of the case 12 when the riser 14 and the nozzle base 38 are in a relatively lower vertical position. However, when the riser 14 and nozzle base 16 move vertically upward, they slide vertically relative to the rotating ring 22 which remains in a relatively stationary, vertical position. As shown in
The rotating ring 22 is rotatably coupled to the nozzle base 16 so that when the nozzle base 16 rotates, the ring 22 synchronously rotates with it. Because the rotating ring 22 is lifted off of the case flange 46 when the nozzle base 16 is extended, the ring 22 “floats” as it is rotating thereby reducing or eliminating friction and drag between the case 12, the rotating ring 22, and the nozzle base 16 as it rotates.
A plurality of magnets 50 are attached to the rotating ring 22 by embedding them within the ring 22 and are disposed at a radially outward portion of the ring 22. The sensor unit 30 is mounted on the outside of the plastic case 12 at a location adjacent to the rotating ring 22. In the illustrated embodiment, the sensor unit 30 includes two Hall-effect sensors (not shown) enclosed within the sensor unit 30. As previously mentioned, Hall-effect sensors provide an electrical output when placed within a magnetic field.
Therefore, as best seen in
The sensor unit 30 employing Hall-effect sensors is advantageous in that the unit 30 is positioned on the outside of the case 12 where it will not come in contact with the water flowing through the irrigation sprinkler 10. Yet once positioned sufficiently close to the magnets 50, the Hall-effect sensors will detect the magnetic fields generated by the magnets 50. Because the case 12, the rotating ring 22 and other nearby components are generally constructed of plastic, interference and distortion of the magnetic fields is minimized.
By employing two Hall-effect sensors within the sensor unit 30, an electrical signal can be generated to provide an indication of the direction of rotation (i.e., counterclockwise or clockwise) of the nozzle assembly. That is, when the magnetic field of one of the magnets 50 passes through one Hall-effect sensor and then passes through the second Hall-effect sensor, the order of receipt by system electronics of the electrical signals generated by each Hall-effect sensor would indicate the direction of rotation.
Additionally, one of the two Hall-effect sensors is used to provide signals from which the speed of rotation can be determined. By employing a plurality of magnets 50 in the rotating ring 22, a separate signal will be generated by the Hall-effect sensor for each magnetic field that passes through it as a result of each magnet. The time differential between each of the passing magnetic fields can be measured by system electronics and thereby, a rotational speed can be calculated.
Although the illustrated embodiment uses Hall-effect sensors, it will be appreciated by those skilled in the art that other types of sensors capable of detecting one or more magnetic fields may be substituted for the Hall-effect sensors illustrated herein. Such magnetic field detection includes not only the detection of the presence of magnetic fields, but also the variations within one or more fields so that changes over time in field strength or direction are detected. Examples of other types of sensors include proximity sensors, reed switch sensors, inductive sensors, magnetoresistive sensors, fiber-optic sensors, flux-gate magnetometers, magnetoinductive magnetometers, anisotropic magnetoresistive sensors, giant magnetoresistive sensors, and bias magnet field sensors.
Still referring to
a and 5b illustrate the rotating ring 22 of
a and 5b show the plurality of projections 56 (or flats or ledges) arranged in an octagonal pattern adapted to mate with the nozzle base and housing grooves 36, 40. However, alternative embodiments may include any coupler arrangement or geometry, including one or more single tabs or other types of projections extending from the rotating ring 22 and mating with the nozzle base 16, one or more tabs or other types of projections extending from the nozzle base 16 and mating with the rotating ring 22, etc.
In the illustrated embodiment, the magnets are connected to the nozzle assembly via the rotating ring 22 which is rotatably and slidably coupled to the nozzle assembly. In alternative embodiments, however, a rotating ring need not be used. Rather, one or more magnets may be connected to a nozzle assembly by directly attaching them to the nozzle assembly or integrally incorporating them with the nozzle assembly so that the magnets are directly carried with and moved by the nozzle assembly.
In the illustrated embodiment, eight magnets 50 are equally spaced about the periphery of the rotating ring 22 so that an arc of about 45° would likely encompass any two adjacent magnets 50. With this resolution, an irrigation rotor that is set for a spray pattern arc as small as 45° should nevertheless provide automatic rotor speed and direction detection capabilities. Alternative embodiments of the invention, however, may use a greater or fewer number of magnets, although such variations may affect speed and direction detection capabilities.
In the illustrated embodiment, the magnets are connected to the nozzle assembly in such a way that they rotate in response to the rotation of the nozzle assembly. In alternative embodiments, one or more magnets are attached to the nozzle assembly so that the magnets move vertically when the nozzle assembly moves from a lower inoperative position to an upper operative position. A sensor unit is disposed adjacent to the nozzle assembly in such a manner that it detects one or more magnetic fields as their associated magnets move vertically. Thus the sensor unit provides a signal that is indicative of the vertical position of the nozzle assembly.
As previously mentioned, alternative embodiments of the invention include the use of various types of sensors that detect magnetic fields (including in some instances the detection of variations over time within one or more magnetic fields). Some of these sensors can detect the presence of a ferrous material that is not permanently magnetized by detecting a variation over time in one or more magnetic fields that have been influenced by the presence of the ferrous material as it passes through the magnetic fields.
Therefore, alternative embodiments of the invention include a movable nozzle assembly having one or more pieces of ferrous material that are not permanently magnetized and that are connected to the nozzle assembly (i.e., integral with the assembly or coupled or attached to the assembly). For example, these pieces of ferrous material could be non-magnetized metal that replaces the magnets 50 that are attached to the rotating ring 22 as shown in
One or more magnetic fields are generated by one or more magnetic field sources located in or near one or more sensors, but not necessarily connected to the nozzle assembly. The magnetic sources can include permanent magnets, electromagnets or an electrical current. Thus as the one or more pieces of ferrous material that are connected to the moving nozzle assembly pass through the one or more magnetic fields, the sensors detect variations over time in these magnetic fields that are caused by the presence of the ferrous material. Accordingly nozzle assembly position, speed of rotation or direction of rotation (or any combination thereof) can be detected.
Thus disclosed is an irrigation sprinkler comprising a nozzle assembly for dispersing water to an area of vegetation by movement of at least a portion of the nozzle assembly. According to one embodiment, the nozzle assembly is rotatable and has a plurality of magnets connected to the nozzle assembly so that they synchronously rotate with it. A sensor unit is mounted adjacent to the magnets and provides electrical signals in response to the magnetic fields produced by the rotating magnets. These electrical signals are used to provide information as to both the direction of rotation and the speed of rotation of the nozzle assembly. This information is transmitted either wirelessly or via wires to a computer or monitor or other device at a central location where a user can easily monitor the operation of a plurality of units.
While the description above refers to particular embodiments of the present invention, it will be understood that many modifications may be made without departing from the spirit thereof. The claims are intended to cover such modifications as would fall within the true scope and spirit of the present invention. The presently disclosed embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the claims rather than the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.
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