A method for sowing an individual seed in a seed location and to a seeder therefor. The method includes arranging a seed on a surface adjacent to an opening that leads to a guide channel that extends to the seed location; flushing the seed from the surface into the opening by directing a fluid over the surface in the direction of the opening; and guiding the seed to a seed location by the guide channel. The seeder has at least one opening that leads to a guide channel that extends to a seed location; a surface that is configured to be arranged adjacent to the at least one opening; and a selectively operable fluid supply for each opening, each fluid supply having at least one nozzle that is arranged for directing fluid over the surface in the direction of the opening.

An assembly line grow pod includes a seeding region, a harvesting region, a track that extends between the seeding region and the harvesting region, a cart including a tray for holding plant matter, and a wheel coupled to the tray, where the wheel is engaged with the track, and a weight sensor positioned on the cart or the track, where the weight sensor is positioned to detect a weight of the plant matter positioned within the cart.

A system for testing for contaminants in an assembly line grow pod includes a tray moving along a track arranged in an assembly line grow pod, a plurality of cells arranged on the tray and a contaminant sensor. Each cell supports seeds, plants, or both, and a selected cell includes side walls and a base that define a cavity. The contaminant sensor is arranged in the cavity of the selected cell. The contaminant sensor includes a sensing device and a control device. The sensing device directly senses a characteristic of a content present in association with the selected cell. The control device is coupled to the sensing device and operable to receive a signal from the sensing device. The control device may determine a likelihood of contamination based on the received signal.

A drop seeder apparatus includes a frame and a bottom plate having a plurality of through holes. A top plate has a plurality of through holes. The top plate is secured in the frame and positioned in a sliding relationship with respect to the bottom plate. A system of legs is configured to adjust a length thereof to accommodate seed trays of varying heights. A slide actuation system is configured to allow a user to slide the top plate across the bottom plate and cause the top plate to automatically return to a default trap position.

A method for pumping seeds to an assembly line grow pods includes releasing seeds to a pipe in fluid communication with a pump, moving water from a water source to the pipe in fluid communication with the pump, combining the seeds released from the tank with the water from the water source in the pipe, and pumping the combination of the seeds released from the tank and the water from the water source to a grow pod line in fluid communication with the pump, and moving the seeds from the grow pod line to one or more carts of an assembly line grow pod.

A seed storage device comprising a plurality of pods connected sequentially. Each pod is adapted to store one or more seeds and adapted to be breachable to facilitate releasing the seeds to a planting location. An associated method of storing seeds comprising placing one or more seeds into a pod of the seed storage device, and an associated method of planting seeds using the seed storage device, are also provided. A completed seed kit comprising the seed storage device with one or more seeds stored in one or more of the pods is also provided.

An automated seed planter may include at least two vacuum cylinders which simultaneously and/or independently pick up and deliver seeds to a single tray. The vacuum cylinders may have a common rotational axis about which the vacuum cylinders rotate. The automated seed planter may include a plurality of vertical seed chutes which receive seeds therein. The vertical seed chutes have open upper and lower ends. A shutter assembly of the seed planter is associated with the lower ends of the vertical seed chutes. The shutter assembly is selectively opens and closes the lower ends of the seed chutes to plant the seeds on the tray. The automated seed planter may include a seed correction assembly including seed wells which receive seeds therein. The seed correction assembly selectively displaces one or more of the seeds from the seed wells to deliver the one or more seeds toward the tray for planting.

The present invention relates to a device and method for sowing seeds. The invention relates more particularly to a device and method for sowing seeds as part of a plant. The system according to the invention comprises a separating device for separating a single seed relative to a remainder of the plurality of seeds, an optical recognition system (9) for recognizing the separated seed, a robot arm device (4) for picking up the separated seed and for sowing the picked-up seed, arid a control unit for controlling the separating device, the optical recognition system (9) and the robot arm device (4). With this system it is possible to sow seeds in a more accurate and less error-prone manner.

The present invention relates to a device and method for sowing seeds. The invention relates more particularly to a device and method for sowing seeds as part of a plant breeding process. The system according to the invention comprises a separating device for separating a single seed relative to a remainder of the plurality of seeds, an optical recognition system for recognizing the separated seed, a robot arm device for picking up the separated seed and for sowing the picked-up seed, and a control unit for controlling the separating device, the optical recognition system and the robot arm device. With this system it is possible to sow seeds in a more accurate and less error-prone manner.

A smart seeder which significantly enhances efficiency in individual seed separation by enabling the seeds supplied onto a transfer plate to be spread more easily so that the seeds do not overlap, and consequently by enabling the seeds to be separated individually. Furthermore, the smart seeder can not only significantly reduce production costs due to the simple structure thereof, but also significantly enhance seed separation efficiency by separating one or multiple seeds, which may comprise fine seeds, such as lettuce seeds, or the like, whether the seeds are small seeds or large seeds.