A harvester selectively harvests edible crowns ready for harvesting. The harvester may include an imaging system for capturing image(s) of the edible crowns and a de-leafing component that removes leaves of the broccoli plant. For example, broccoli plants typically have an abundance of leaves that reside beneath, alongside of, and even above the edible crowns. The leaves may conceal the edible crowns and impact a quality of the image(s). The de-leafing component may be positioned in front of the imaging system, relative to a direction of travel of the harvester, to remove the leaves and isolate or expose the edible crown. Therein, the imaging system may image the edible crowns for use in determining whether the edible crowns are ready for harvesting.

Provided is a traveling vehicle which is configured to be manually operable and to be capable of being prevented from collision, and which can be assembled more easily. This traveling vehicle is provided with a traveling vehicle body on which a first control unit for controlling traveling is mounted, and an operation unit which enables the manual operation of the traveling vehicle body. The operation unit is provided with a housing having a connection section removably connected to the traveling vehicle body. The housing is integral with manual operation sections enabling an input of instructive information for traveling into the first control unit, and also with an obstacle sensor for detecting an obstacle present in the direction of movement of the vehicle body and transmitting the result of detection to the first control unit.

An end effector for harvesting edible crowns of broccoli plants. The end effector may include a body, fingers pivotably coupled to the body, and a rotary actuator disposed in the body. The rotary actuator operably couples to the fingers via one or more linkages and is configured to transition the fingers between an open position and a closed position. In the closed position, an edible crown is retained within the end effector, while in the open position, the edible crown is released from the end effector. A cutting mechanism of the end effector severs the edible crown from a stalk of the broccoli plant. A robotic arm may position the end effector relative to the edible crown for harvesting.

An end effector for harvesting edible crowns of broccoli plants. The end effector may include a body, fingers pivotably coupled to the body, and a rotary actuator disposed in the body. The rotary actuator operably couples to the fingers via one or more linkages and is configured to transition the fingers between an open position and a closed position. In the closed position, an edible crown is retained within the end effector, while in the open position, the edible crown is released from the end effector. A cutting mechanism of the end effector severs the edible crown from a stalk of the broccoli plant. A robotic arm may position the end effector relative to the edible crown for harvesting.

An automated aquaponics system and method of use comprising an autonomously operated plant growing conveyor belt system that allows the plant to germinate from seed capsules to fully grown plants that are then fully harvested for consumption while the plant roots are cut, chopped, cooked, and processed for the appropriate consumption of the aquarian species that resides within the aquaponic ecosystem.

A method includes: at an autonomous vehicle and during a first operating period, capturing a first set of images of a plant; calculating a location of the plant based on the first set of images; extracting an initial value of a plant metric of the plant based on the first set of images; predicting a predicted value of the plant metric of the plant at a time based on the initial value of the plant metric of the plant and a set of global condition data. The method also includes, at the autonomous vehicle and during a second operating period concurrent with the time: capturing a second set of images of the plant; identifying the plant based on the second set of images and the location of the plant; and executing an agricultural operation on the plant based on the predicted value of the plant metric.

A method includes: at an autonomous vehicle and during a first operating period, capturing a first set of images of a plant; calculating a location of the plant based on the first set of images; extracting an initial value of a plant metric of the plant based on the first set of images; predicting a predicted value of the plant metric of the plant at a time based on the initial value of the plant metric of the plant and a set of global condition data. The method also includes, at the autonomous vehicle and during a second operating period concurrent with the time: capturing a second set of images of the plant; identifying the plant based on the second set of images and the location of the plant; and executing an agricultural operation on the plant based on the predicted value of the plant metric.

A method includes: at an autonomous vehicle and during a first operating period, capturing a first set of images of a plant; calculating a location of the plant based on the first set of images; extracting an initial value of a plant metric of the plant based on the first set of images; predicting a time series of the plant metric of the plant based on the plant profile of the plant and a set of global condition data. The method also includes: generating a timing recommendation for an agricultural operation based on the plant profile of each plant in the set of plants, the timing recommendation designating a target time.

The invention relates to a device comprising a filling unit for filling containers with a product. The invention furthermore relates to a system comprising such a device and to a harvesting machine provided with such a system. Lastly, the invention relates to a method for filling containers with a product by means of a filling unit.

A support frame; a cut and lift mechanism coupled to the support frame; a tool carrying platform coupled to the cut and lift mechanism; an outer leaf removal device coupled to the tool carrying platform; a cutting tool coupled to the tool carrying platform; a controller in data communication with the cut and lift robot; and a plant center locator in data communication with the controller.