A seed level managing system includes a seed tank configured to contain seeds, a plurality of seed level sensors placed on a sidewall of the seed tank, a surface detecting sensor, and a controller. The controller includes one or more processors, one or more memory modules, and machine readable instructions stored in the one or more memory modules that, when executed by the one or more processors, cause the controller to receive first information from the plurality of seed level sensors; receive second information from the surface detecting sensor and determine a number of the seeds in the seed tank based on the first information and the second information.

Disclosed herein are precision seeder heads and seeder components that include precision seeder heads. According to some embodiments, a precision seeder head includes a seed queue tube having an inside circumference that is sized to accommodate one seed at any vertical location, a first seed hold that selectively blocks the seed queue tube when located in a default position and selectively unblocks the seed queue tube when located in the release position, and an optical sensor positioned at a vertical position below the first seed hold, the optical sensor adapted to detect seeds dispensed from the seed queue tube.

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 method for placing seeds inside a growth substrate by a seed insertion device including the steps of: arranging the seed insertion device in contact with the growth substrate such that a tip of the seed insertion device penetrates through an outer surface of the growth substrate; creating a growth pocket inside the growth substrate with the seed insertion device; supplying seeds to the growth pocket of the growth substrate via the seed insertion device; removing the seed insertion device from contact with the growth substrate; and closing the growth pocket by elastic force of the growth substrate for forming a closed growth pocket such that the seeds remain in the closed growth pocket inside the growth substrate.

A plant draw-in device and a plant body transplantation system that can draw roots of plant bodies into holes reliably with a simple structure, so that there is no need of monitoring or manual operation for roots insertion and the production efficiency can be improved. The plant draw-in device 110 includes a draw-in tube 111 that can be disposed below a hole 121, a draw-in member 113 provided such as to be capable of protruding from the draw-in tube 111, and a drive unit 114 that reciprocally moves the draw-in member 113 such as to come out from, and retract into, the draw-in tube 111. The draw-in member 113 is formed such that a portion thereof protruding from the draw-in tube 111 deforms and spreads outward.

There is provided a seedbed holding unit capable of reliably and firmly holding a seedbed with a simple structure, causing no damage to a plant. A seedbed holding unit 160 that holds a seedbed B used in plant cultivation includes a first holding member 170 and a second holding member 180 that are rotatable relative to each other about a predetermined rotation axis A, the first holding member 170 is provided with a first claw part 173 in a fixed state, the second holding member 180 is provided with a second claw part 183 in a fixed state, and the seedbed B is held between the first claw part 173 and the second claw part 183 by rotating the first holding member 170 and the second holding member 180 relative to each other.

A conveyor system (4, 5) moves vertical poles (2) in an agricultural facility between a growing area (20) and a workstation (W). Each pole carries plant growing containers (3) at multiple levels (H1-H9). An irrigation reservoir (30) may be mounted atop each pole. Irrigation lines (31-33) from the reservoir may be individually metered (35) at each level to compensate for differing water pressure with height. Sensors (40) in the reservoir and at each level of the poles may provide a controller (36) with data input. The controller may impose different growing conditions in different areas of the facility, including vertically different grow areas (20A, 20B), and controls pole movements and locations selectively to provide a sequence of poles at the workstation ready to harvest on a demand schedule. The workstation may have multiple heights (W1, W2, W3) for tall poles that increase plant density per facility footprint.

The invention presents technology for elevated cultivation comprising an automatic paver and man-machine collaboration matrix control method in the field of agricultural equipment.

The substrate auto-paver for the table-top culture machine is mainly composed of a moving car, a matrix and a matrix-packing mechanism, the substrate material in the cabinet, an evenly paving mechanism that realizes double-sided blanking, and a remote control. The manual push-pull arm is employed to ensure that the return wheel touches the ground, using the matrix agencies to van automatically. The remote control is used to move the car into the elevated inter-row cultivation bed, and then, the double-sided blanking and evenly paving mechanism is automatically activated until the track wheel falls into the slot on the skeleton. By means of the bending type of chain transmission mechanism, the soilless culture substrates are automatically conveyed owing to the bilateral symmetry of blanking trough. A moving trolley drives the stirring device along the elevated bed. Thus, an evenly mixed matrix is obtained for cultivation in the tank. A rubber band, which is fixed on the back board of the stirring device, makes the matrix flat and level. The challenges of substrate packing, transportation, and mobile paving are being solved through collaboration between many institutions and by means of some artificial automatic intervention, which can help realize good adaptability and convenient handling.

A device (1) for administering a fluid to substrate bodies provided with a plant includes a frame (2), at least one position station provided on the frame (2) for one or more substrate bodies and at least one fluid device at the position station for urging the fluid into the substrate body, wherein the fluid device includes at least one fluid dispenser, a source (5) of fluid and a conduit (15) for fluid situated in between them, as well as pressure element (6) for supplying a dose of fluid under pressure to the fluid dispenser.

The present invention relates to an apparatus for breeding plants having at least two units arranged in the apparatus for the reception of a plant, wherein at least two units are arranged in a first row and at least one of these units is movable relative to at least one further unit of the first row so that their spacing from one another is changeable.