Robotic systems and methods for harvesting agricultural produce along multiple rows crops are disclosed. A mobile platform may include a robotic arm having a gripping tool and repositionable catch for collecting harvested target objects. A vision system may facilitate the identification of target objects and an associated controller may coordinate the various operational functions.

The invention relates to the design of mobile platforms for vehicles used mostly for agricultural purposes. The rotary support includes a platform mounting attachment in the form of a gimbal, whose flanges enable its attachment, respectively, to the vehicle support structure and the lower surface of the platform, and two platform position adjusters located on said support structure. Therein, each platform position adjuster includes an electric drive with a linear displacement unit based on screw-nut transmission and a carriage configured to move along a vertical guide and connected to the linear displacement unit with a pin joint. The support shelf of the carriage bears a push rod made in the form of struts ending with supports and having swivel joints between said supports and struts. Therein, the push rod supports are configured for mounting them on the support shelf of the carriage and on the platform, in this latter case eccentrically to the rotation axes of the gimbal. Thus, the reliability of the structure and the speed of platform stabilization in space are improved.

The invention relates to the design of mobile platforms for vehicles used mostly for agricultural purposes. The rotary support includes a platform mounting attachment in the form of a gimbal, whose flanges enable its attachment, respectively, to the vehicle support structure and the lower surface of the platform, and two platform position adjusters located on said support structure. Therein, each platform position adjuster includes an electric drive with a linear displacement unit based on screw-nut transmission and a carriage configured to move along a vertical guide and connected to the linear displacement unit with a pin joint. The support shelf of the carriage bears a push rod made in the form of struts ending with supports and having swivel joints between said supports and struts. Therein, the push rod supports are configured for mounting them on the support shelf of the carriage and on the platform, in this latter case eccentrically to the rotation axes of the gimbal. Thus, the reliability of the structure and the speed of platform stabilization in space are improved.

A robotic harvesting platform system for harvesting or diluting fruits in an orchard, the system comprising: a support frame, an elongated platform attached to said support frame, two or more robotic harvesting units associated with said elongated platform at different points thereon, one or more fruit detection units for identifying location and position of said fruits, wherein: said robotic harvesting platform system is designed to harvest fruits from a tree(s) at different heights simultaneously; and each robotic harvesting unit is designed to operate independently from the other robotic harvesting units.

A mobile picking platform system includes a mobile picking platform having a mobile carriage with a superstructure supporting multiple adjustable picking stations. A storage box carrier on the mobile picking platform has a pick position with storage boxes held at optimum heights for access by pickers on the picking stations, an unload position in which full storage boxes are unloaded onto a ground surface, and a load position for receiving empty storage boxes. A storage unit carries empty storage boxes and facilitates transfer of storage boxes to the mobile picking platform. A shuttle trailer may also be included in the system to transfer empty storage boxes to the mobile picking platform and storage unit. The shuttle trailer has a down position in which full storage boxes may be picked up from a ground surface, and an up position for transferring storage boxes to the storage unit or mobile picking platform.

A mobile picking platform system includes a mobile picking platform having a mobile carriage with a superstructure supporting multiple adjustable picking stations. A storage box carrier on the mobile picking platform has a pick position with storage boxes held at optimum heights for access by pickers on the picking stations, an unload position in which full storage boxes are unloaded onto a ground surface, and a load position for receiving empty storage boxes. A storage unit carries empty storage boxes and facilitates transfer of storage boxes to the mobile picking platform. A shuttle trailer may also be included in the system to transfer empty storage boxes to the mobile picking platform and storage unit. The shuttle trailer has a down position in which full storage boxes may be picked up from a ground surface, and an up position for transferring storage boxes to the storage unit or mobile picking platform.

The present invention provides an autonomous harvesting system designed to be mounted onto a standard collection bin/wagon for autonomously harvesting and filing the bin.

The present invention provides a fruit's protection system designed to be mounted onto a standard collection bin for safely placing harvested fruits inside the collection bin without harming same.

The present invention provides a fruit's protection system designed to be mounted onto a standard collection bin for safely placing harvested fruits inside the collection bin without harming same.

The present invention relates to a harvesting machine comprising a shaking mechanism operable to shake fruit or nuts from a tree or bush; a deflection plate for directing the fruit or nuts to an area away from the base of the tree or bush; and a device for moving fruit or nuts from the base of the tree or bush to the area away from the base of the tree or bush. The deflection plate may be positioned at an angle of between 0 to about 75 relative to the horizontal.