41 results about "Center pivot irrigation" patented technology

A GPS-based control system for irrigation systems includes a power supply, a nonvolatile memory for storing a first set of coordinates corresponding to a reference position for the irrigation system, circuitry for receiving GPS data and using the data to generate a second set of coordinates corresponding to a current position of the irrigation system, and a microprocessor for calculating the azimuth and the distance between the reference position and the current position using the first and second sets of coordinates. The control system communicates with a main controller of the irrigation system to control a function of the irrigation system, such as stopping, reversing, end gun operation, application rate, or other auxiliary output, at a selected distance or azimuth value of the current position relative to the reference position. The control system can be used with either a center pivot irrigation system or a linear move irrigation system.

A system and method for determining a position of a center pivot irrigation system includes positioning a tower unit on the rotatable arm of the irrigation system, determining a distance between the arm's rotation center and the tower unit, calculating coordinates of the tower unit along a path of the tower unit as the arm rotates, and associating an action of the irrigation system with coordinates of the tower unit location that correspond to the position of the arm where the action is to occur. Optionally, the action of the irrigation system and the coordinates of the location of the tower unit are downloaded to a remote unit located adjacent to the irrigation system. Optionally, current location coordinates of the tower unit are determined using a GPS receiver at the tower unit. Optionally, the current location coordinates are transmitted from the tower unit to the remote unit. Optionally, the current location coordinates are compared to the coordinates of the location of the action. If a substantial match of the current location coordinates with the location coordinates associated with an action is detected, the action may be initiated by the remote unit through controls of the irrigation system.

A system and method for determining a position of a center pivot irrigation system includes positioning a tower unit on the rotatable arm of the irrigation system, determining a distance between the arm's rotation center and the tower unit, calculating coordinates of the tower unit along a path of the tower unit as the arm rotates, and associating an action of the irrigation system with coordinates of the tower unit location that correspond to the position of the arm where the action is to occur. Optionally, the action of the irrigation system and the coordinates of the location of the tower unit are downloaded to a remote unit located adjacent to the irrigation system. Optionally, current location coordinates of the tower unit are determined using a GPS receiver at the tower unit. Optionally, the current location coordinates are transmitted from the tower unit to the remote unit. Optionally, the current location coordinates are compared to the coordinates of the location of the action. If a substantial match of the current location coordinates with the location coordinates associated with an action is detected, the action may be initiated by the remote unit through controls of the irrigation system.

A flotation drive assembly for mechanized irrigation systems such as a corner pivot irrigation machine, a center pivot irrigation machine or a linear move irrigation machine wherein the flotation drive assembly improves upon the field traction of the mechanized agricultural irrigational systems and which improves the resistance to wheel track rutting that may occur during the normal operation of the systems. The flotation drive assembly of this invention is designed so that the gearbox which drives the wheel / tire assemblies at the opposite ends of the main frame of the drive unit or tower is mounted so as not to support the weight of the tower or the water contained therein.

A method of optimizing water applications of a center pivot irrigation system. The field is mapped to determine the yield potentials of various parts of the field. The field map is divided into sectors or zones and the yield potentials of those sectors or zones are determined. The number of sectors or zones to be irrigated is dependent upon the water flow available to the irrigation system. Only those sectors or zones which can receive adequate irrigating water to achieve the predetermined water application depth will be irrigated.

To allow for optimal uniform application of irrigation fluid in a field space outfitted with a center pivot irrigation machine having a main pipeline and an auxiliary or corner pipeline, the auxiliary pipeline is operable to both lead and lag the main pipeline as the main pipeline makes a progressive rotation in a single direction through the field space. In one embodiment a control system for the irrigation machine comprises a buried cable control system. In another embodiment a control system comprises a global positioning satellite control system. In a third embodiment a control system comprises at least two position sensing devices, a first device for sensing an angle of the main pipeline with respect to a center tower and a second device for sensing an angle between the main pipeline and the auxiliary pipeline, and a speed controlling device for controlling a speed of rotation of the main and auxiliary pipelines.

A flotation drive wheel is provided for a self-propelled irrigation system such as a center pivot irrigation system, a linear irrigation system or a corner irrigation system. The flotation drive wheel of this invention comprises a hub portion which is directly attached to an associated gearbox of the conventional drive tower. A metal band or plate is welded to the outer periphery of the hub portion of the wheel with a plurality of pivotal flotation shoes being attached to the band or plate. The pivotal shoes include structure for preventing soil from being pushed laterally of the flotation wheel and from being pushed forwardly from the drive wheel. The flotation wheel of this invention substantially eliminates the creation of wheel ruts or tracks.

A corner unit guidance control system for use with a corner unit that is part of a center pivot irrigation system includes a primary antenna, a secondary antenna, a receiver, and a controller. The primary antenna and the secondary antenna may receive signals from at least one external positional information source. The receiver may be in communication with the antennas and operable to process the signals to produce position data corresponding to a current position of a wheel and altitude data about the height of the antennas. The controller may be in communication with the receiver and may be programmed to steer the wheel to a heading corresponding to a difference between the current position of the wheel and a point along the path and further programmed to calculate a tilt angle from the altitude data and adjust the heading based on the tilt angle.

An exemplary embodiment relates to a non-pneumatic tire for a center pivot irrigation system comprising two arcuate half-tire segments, the segments having two sidewalls connected by an outer circumferential wall and an inner circumferential wall; a plurality of transverse traction cleats circumferentially spaced on the outer circumferential wall extending between the side walls, the cleats having a rounded tip; a pair of connecting cleats at the ends of the half-tire segments having a plurality of apertures adapted for use in connecting the two arcuate half-tire segments; and a plurality of connectors adapted for insertion into the apertures wherein the cleats are tapered in width having a ratio of the center width of the cleat to the edge width of the cleat of at least about 1.25:1.

A flotation drive assembly for mechanized irrigation systems such as a corner pivot irrigation machine, a center pivot irrigation machine or a linear move irrigation machine wherein the flotation drive assembly improves upon the field traction of the mechanized agricultural irrigational systems and which improves the resistance to wheel track rutting that may occur during the normal operation of the systems. The flotation drive assembly of this invention is designed so that the gearbox which drives the wheel / tire assemblies at the opposite ends of the main frame of the drive unit or tower is mounted so as not to support the weight of the tower or the water contained therein.

The present invention provides a system and method for analyzing sensor data related to an irrigation system. According to a preferred embodiment, the system includes algorithms for analyzing real-time, near real-time and historical data acquired from sensors in communication with a mechanized irrigation machine. Further, the algorithms of the present invention system may analyze collected sensor data to determine if an event has occurred or is predicted to occur. Further, the algorithms of the present invention may provide commands to an irrigation machine and notifications to users. According to further aspects of the present invention, the algorithms of the present invention may preferably apply machine learning and other data analysis tools to detect maintenance patterns, geographic trends, environmental trends, and to provide predictive analysis for future events.