A harvest route generator system generates a harvest route for a harvesting machine. The harvest route generator system has a route generator that receives lodged crop information, from a sensor system, indicative of a characteristic of a lodged crop in a field and generates a harvesting route through the field for the harvesting machine, based on the lodged crop information. The harvest route generator system also has a communication component that communicates the harvesting route through the field to the harvesting machine.

The present invention relates to a turn system actuated by hydraulic cylinders, applied to the four wheels of sugar-cane harvesters, wherein the harvester (80) comprises a rear axle (23) and a front axle (24), with wheel assemblies (9) associated to the axles (23, 24), wherein the rear axle (23) and the front axle (24) have a turn system, the one of the rear axle (23) being actuated by means of a double-action rear hydraulic cylinder (1) and that of the front axle (24) being actuated by means of a double-action front hydraulic cylinder (11), the hydraulic cylinders (1, 11) receiving a flow of oil through at least one flow divider (61) connected to an ortibrol (65) actuated by means of a steering wheel (60) of the harvester (80), the flow of oil received by the flow divider (61) being proportional to a factor related to the turn of the steering wheel (60), the turn system enabling the turn of the wheel assemblies (9) in amplitude ranging from 0.5 to 40 degrees, to the right or to the left, with respect to the longitudinal axis of the harvester (80).

An operation management system for a vehicle controllable by an operator to perform various vehicle actions, the system including a processor, a memory, and a human-machine interface. The processor is configured to record sequences of operator-initiated vehicle actions and compare the sequences. If at least two of the sequences contain the same operator-initiated vehicle actions, identify the at least two of the sequences as matching sequences, and communicate, by way of the human-machine interface, to the operator of the vehicle a suggested operating sequence based on the matching sequences.

An agricultural material baling system comprises, in one example, a bale forming component configured to form a bale of agricultural material from a terrain, and a control system configured to determine that the bale is to be released from the baling system onto the terrain, determine that a current location of the baling system has a slope above a threshold, determine a different location, that is spaced apart from the current location, for releasing the bale onto the terrain, and provide an output indicative of the different location. In one example, the control system is configured to receive yield data indicative of a volume of agricultural material in a path of the baler and to control the baling system based on the yield data. In one example, the yield data is obtained from a raking operation that rakes the agricultural material into a windrow.

Systems and methods for planning a path of a vehicle are provided. One system comprises a location-determining receiver for determining location data representing a current vehicle location and a guidance module for identifying at least one geospatial region encompassing the current vehicle location based on geographical information retrieved from a guidance database. The guidance module is capable of generating a list of potential guidance lines based on the at least one geospatial region, each geospatial region being associated with at least one guidance line, each of the potential guidance lines on the list ranked based on one or more guidance criteria retrieved from the guidance database. The system further includes a user interface for displaying the guidance lines on the list to an operator of the vehicle for selection of a selected one of the potential guidance lines for controlling the path of the vehicle.

A harvest route generator system generates a harvest route for a harvesting machine. The harvest route generator system has a route generator that receives lodged crop information, from a sensor system, indicative of a characteristic of a lodged crop in a field and generates a harvesting route through the field for the harvesting machine, based on the lodged crop information. The harvest route generator system also has a communication component that communicates the harvesting route through the field to the harvesting machine.

The present invention is related to a method for harvesting crops from a field and to a method for working a field by towing an apparatus such as a tilling apparatus, wherein the methods of the invention employ manned and unmanned vehicles. The operation and movement of the unmanned vehicles is controlled by the drivers of the manned vehicles which are continuously in the vicinity of the unmanned vehicles. The harvesting method involves at least the driver of a harvesting vehicle such as a combine harvester and the driver of a crop collecting vehicle such as a truck, wherein the drivers control the operation of one or more unmanned crop carts, operated to receive harvested crops from the harvesting vehicle during a harvesting phase and deliver harvested crop to the crop collecting vehicle during a subsequent delivery phase The control effected by the driver of the harvesting vehicle and the driver of the collecting vehicle is such that each driver is capable of visually inspecting the crop cart's operation during the totality of the harvesting and delivery phases respectively. The invention is equally related to a method for working an agricultural field wherein an agricultural apparatus, such as a tillage apparatus, is towed through the field, by one or more unmanned vehicles, while the operation of the unmanned vehicles is controlled by the operator of a manned vehicle that is moving along with the unmanned vehicles through the field.

Embodiments herein disclose methods and systems for optimizing the productivity and improving the stability of electric vehicles by sensing field size and soil condition and automatically assisting the vehicle to turn by rotating inner wheels faster as compared to outer wheels of the vehicle and rotating front wheels of the vehicle faster as compared to rear wheels of the vehicle, and selectively braking respective wheel during headland operations. Embodiments herein enable operators to attain tight headland turns with lower head land space. Embodiments herein can detect a plurality of parameters such as, field conditions, soil condition, implements(s) connected to the vehicle, and so on, and control the turning radius of the vehicle as per requirement in at least one mode.

The present disclosure relates to a hydraulic steering device for an agricultural work vehicle comprising a steering pump for supplying working fluid; an automatic steering unit which is connected to the steering pump, and which changes, according to automatic steering performed by a control part, the traveling direction of the agricultural work vehicle by using the working fluid supplied from the steering pump; a manual steering unit which is connected to each of the steering pump and the automatic steering unit, and which changes, according to manual steering performed by the operation of a steering wheel, the traveling direction of the agricultural work vehicle, and a manual switching unit connected to each of the steering pump and the manual steering unit.

An aerator for a turf surface has a traction control, an OPC bail, and an aeration bail capable of single handed operation. A controller automatically lowers a tine head to begin aerating at a start location marked when the aeration bail is closed and lifts the tine head to end aeration at an end location marked when the aeration bail is released. The controller further causes the tines that enter the turf surface at the start location to penetrate to a desired hole depth. The controller also automatically adjusts ground speed to maintain a desired hole spacing during an aeration pass, but permits the operator to speed up during a turnaround between passes with a steerable front wheel freewheeling to mitigate wheel scrubbing. A handle assembly having a spring counterbalance is height adjustable and automatically engages a parking brake when placed in an upright non-operating position.