In order to reduce a possibility of damaging a seedling in the event of transplant of unit nursery beds when the seedlings are replanted from a seedling tray that supports unit nursery beds individually planted with seedlings germinated from seeds to a hydroponic panel capable of securing a longer seedling-to-seedling distance, a seedling transplanter (1) includes: a seedling tray (3) supported by a frame (2) and configured to support a nursery bed (7) having unit nursery beds (71) separable from each other and arranged in two directions on a plane; a hydroponic panel (4) supported by the frame (2) and provided with holes (41) for storing the unit nursery beds (71), the hydroponic panel (4) serving as a transplant destination of the unit nursery beds (71) on the seedling tray (3); and a holding member (5) supported by the frame (2) pivotally around a vertical axis and vertically movably to separate the unit nursery bed (71) from the nursery bed (7) by holding any one or a plurality of the unit nursery beds (71) on the seedling tray (3) arranged in the outermost side of the nursery bed (7) from a lateral face side of the unit nursery bed (71) in a width direction of the unit nursery bed (71), insert the unit nursery bed (71) into the hole (41) of the hydroponic panel (4), and release the unit nursery bed (71).

In order to reduce a possibility of damaging a seedling in the event of transplant of unit nursery beds when the seedlings are replanted from a seedling tray that supports unit nursery beds individually planted with seedlings germinated from seeds to a hydroponic panel capable of securing a longer seedling-to-seedling distance, a seedling transplanter (1) includes: a seedling tray (3) supported by a frame (2) and configured to support a nursery bed (7) having unit nursery beds (71) separable from each other and arranged in two directions on a plane; a hydroponic panel (4) supported by the frame (2) and provided with holes (41) for storing the unit nursery beds (71), the hydroponic panel (4) serving as a transplant destination of the unit nursery beds (71) on the seedling tray (3); and a holding member (5) supported by the frame (2) pivotally around a vertical axis and vertically movably to separate the unit nursery bed (71) from the nursery bed (7) by holding any one or a plurality of the unit nursery beds (71) on the seedling tray (3) arranged in the outermost side of the nursery bed (7) from a lateral face side of the unit nursery bed (71) in a width direction of the unit nursery bed (71), insert the unit nursery bed (71) into the hole (41) of the hydroponic panel (4), and release the unit nursery bed (71).

There is provided a pick-and-plant head for planting plant cuttings in a cultivation medium. The pick-and-plant head is provided with a grasper comprising opposed grasping surfaces for grasping a portion of a cutting between them and with an abutment that abuts a cutting. The grasper and abutment are moveable relative to one another and are arranged so that during release of a cutting from the grasper the abutment passes between the opposed grasping surfaces and the cutting is abutted by the abutment.

Disclosed are a plant growth management system and a control method thereof. A station device of the plant growth management system includes a flowerpot detector configured detect entry of a movable flowerpot device and to generate a detection signal according to whether entry of the movable flowerpot device is detected, a wireless charger configured to wirelessly supply power to the movable flowerpot device according to the detection signal, and a water supply device configured to supply water to a flowerpot included in the movable flowerpot device according to the detection signal, wherein the movable flowerpot device includes an obstacle detection sensor and a solar detection sensor, performs autonomous driving based on the obstacle detection sensor and the solar detection sensor, searches for a space, an illuminance value of which is equal to or greater than a preset illuminance value, through the autonomous driving, and performs rotational motion in the searched space.

A method of potting a tree, wherein the method includes the steps of inserting the root system of the tree into the lumen of the pot, and supplying a particulate substrate to the pot to cover the root system using an apparatus including a supply system. To pot trees quicker, the supply system includes i) a buffer, and ii) at least one chute, wherein the method includes providing the buffer with a predetermined amount of particulate substrate, and batch-wise release of the particulate material in the buffer to provide the pot with the particulate material from the buffer via the at least one chute by gravity.

An extendable plant tray assembly comprising a plurality of plant holders in a grid structure, wherein in a first direction said plant holders are movably connected through an extension system arranged to move said assembly between a retracted position and an extended position, the assembly including at least one grid structure element holding a plurality of plant holders in a second direction transverse to said first direction, wherein the plurality of plant holders are arranged on the at least one grid structure element in a staggered manner, alternating a plant holder with a plant holder receiving space, wherein the extension system comprises extendable connection members which are configured to connect at least two grid structure elements, and wherein the extendable connection members are detachably connected to said at least two grid structure elements.

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.

Crops, for example microgreens, may be aeroponically grown from seed on substrates. The substrates may be seeded with the substrates in a horizontal position, and then arranged vertically for germination and further growth. A gelling material in solution, with the gelling material for example a gellum, may be applied to the substrates, while in the horizontal position, so that the seeds are retained on the substrates when the substrates are moved to a vertical position.

A pick-and-plant head for planting plant cuttings in a cultivation medium. The pick-and-plant head is provided with a grasper including opposed grasping surfaces for grasping a portion of a cutting between them and with an abutment that abuts a cutting. The grasper and abutment are moveable relative to one another and are arranged so that during release of a cutting from the grasper the abutment passes between the opposed grasping surfaces and the cutting is abutted by the abutment.

A positioning device for a plant container having a lip. The positioning device has an extension arm with a hook rigidly connected at one end and a handle rigidly connected at the other end. The positioning device is utilized to move a plant container by engaging the hook with the plant container's lip and then dragging the plant container to a predetermined position. In a preferred embodiment the plant container is a nursery pot.