A trailer brake system that generates load-dependent braking forces. Variable trailer load information is used to generate load-dependent control signals which serve to control an electrically-controlled proportional valve. A load sensing valve serves to modify brake command signals in dependence on a control pressure that is regulated by the proportional valve.

Disclosed are an intelligent pesticide tank assembly and a plant protection machinery. The intelligent pesticide tank assembly includes a cover body and a measuring assembly, wherein the measuring assembly can be arranged to be extended into a pesticide tank body, and the cover body is arranged to be capable of being connected to the pesticide tank body and to enable the measuring assembly to be pressed and fixed onto the pesticide tank body. When the intelligent pesticide tank assembly is disassembled, the measuring assembly can be axially inserted or pulled out, and is then pressed and fixed by using the cover body, so that the measuring assembly is prevented from rotating together with the cover body when the cover body is tightened, and the disassembly of various components can thus be easily completed.

Various embodiments of an apparatus, methods, systems and computer program products described herein are directed to an agricultural observation and treatment system and method of operation. The agricultural treatment system may determine a first real-world geo-spatial location of the treatment system. The system can receive captured images depicting real-world agricultural objects of a geographic scene. The system can associate captured images with the determined geo-spatial location of the treatment system. The treatment system can identify, from a group of mapped and indexed images, images having a second real-word geo-spatial location that is proximate with the first real-world geo-spatial location. The treatment system can compare at least a portion of the identified images with at least a portion of the captured images. The treatment system can determine a target object and emit a fluid projectile at the target object using a treatment device.

Various embodiments of an apparatus, methods, systems and computer program products described herein are directed to an agricultural observation and treatment system and method of operation. The agricultural treatment system may determine a first real-world geo-spatial location of the treatment system. The system can receive captured images depicting real-world agricultural objects of a geographic scene. The system can associate captured images with the determined geo-spatial location of the treatment system. The treatment system can identify, from a group of mapped and indexed images, images having a second real-word geo-spatial location that is proximate with the first real-world geo-spatial location. The treatment system can compare at least a portion of the identified images with at least a portion of the captured images. The treatment system can determine a target object and emit a fluid projectile at the target object using a treatment device.

An aerial vehicle includes a liquid chemical tank, at least one spray unit, a plurality of sensors, a processing unit, and an output unit. The processing unit is configured to generate a spray record for an environment within which the aerial vehicle is operating, the spray record comprising: information over a time period of at least one spray condition relating to one or more of the at least one spray unit for the aerial vehicle operating within the environment over the time period, the determined air movement direction relative to the projection of the fore-aft axis onto the ground over the time period, and the determined air movement speed relative to the ground over the time period. The output unit is configured to output the spray record.

An aerial vehicle includes a liquid chemical tank, at least one spray unit, at least one actuator, a plurality of sensors, and a processing unit. The processing unit is configured to determine an air movement direction relative to a projection of the fore-aft axis onto the ground and determine an air movement speed relative to the ground, the determination comprising utilization of the speed of the aerial vehicle, the air movement direction relative to the aerial vehicle with respect to the fore-aft axis of the aerial vehicle and the air movement speed relative to the aerial vehicle. The processing unit is configured to control at least one flying operation of the aerial vehicle and/or control the at least one actuator.

A product system for an agricultural sprayer can include a product tank configured to store a first volume of an agricultural product. A second volume of the agricultural product can be positioned within a flow assembly after the fill mode. A reclaim system can be configured to provide the agricultural product within the flow assembly to the product tank. A computing system can be communicatively coupled with the reclaim system and configured to determine an open volume of the product tank based on data captured by the tank sensor and activate a reclaim mode of the reclaim system to move the second volume of the agricultural product from the flow assembly to the product tank when the open volume can be greater than the second volume of the agricultural product.

An intelligent, automated system for loading agricultural product application equipment is provided in which a control system can determine a necessary amount of product for completing a field operation and can automatically couple with a tendering system to receive such product at an optimal time and location. The control system can determine a current amount of product, a projected amount of product necessary to complete a field operation and a refill amount of product from the current amount and the projected amount, then transmit the refill amount to the tender. The control system can further determine whether a position of the equipment relative to the tender is within a threshold, and whether an intake coupler of the equipment is connected to a supply coupler of the tender, and can control valve(s) to open and close channel(s) for loading fluid into the storage tank.

A twin-fluid atomized aerial spray system and method of aerial spraying includes flying an atomized spray delivery system with an unmanned aerial system. The atomized spray delivery system includes a first fluid delivery path, a second fluid delivery path and a spray nozzle. The first fluid delivery path has a liquid tank and the second fluid delivery path has a compressed gas tank, wherein the first and second fluid delivery paths deliver respective fluids to the spray nozzle. Liquid from the liquid tank is atomized with compressed gas from the compressed gas tank at the spray nozzle and delivers the atomized spray from the spray nozzle.

An agricultural product application implement includes a system and method for indicating an amount of fluid stored. A pressure transducer installed at the sump of a fluid tank electronically measures and displays a fluid depth. Instrumentation, such as an instrument cluster unit for the implement, is programmed via software to convert the voltage output of the pressure transducer to a volume measurement displayed in the operator's line of sight. Software within the instrument cluster unit for self-calibrating accounts for varying densities of different chemical solutions. The pressure transducer is used in conjunction with a transfer medium to prevent corrosive chemical solutions from contacting the pressure transducer.