A drive unit in a controlled agricultural environment increases a distance between an alignment element and a drive element in order to receive a plant support structure that is oriented non-vertically so that the plant support structure rests on the drive element or the alignment element. The drive unit decreases the distance between the alignment element and the drive element so that the alignment element or the drive element rests on the plant support structure. The drive element conveys the plant support structure along a direction of conveyance.

A method of monitoring at least one aspect in a vegetation wall system and an apparatus for doing the same. The method comprising measuring, by a sensor, a first component and a second component in the vegetation wall system; determining, by a processor, a change in the at least one aspect based on: the first component, the second component, and an amount of time between the measurement of the first component and the second component; determining whether the change in at least one aspect is outside a threshold range; and in response to determining the change in the at least one aspect is outside the threshold range, determining an anomalous condition exists.

The invention is a customizable, slidable shelving and support apparati and system for supporting, storing and accessing horticultural and agricultural specimens within growing spaces, allowing growers to utilize the maximum amount of their linear horizontal and vertical grow space and service specific areas of the garden enterprise while also allowing for maximum workspace through the use of a table and track system that provides stackable options of multiple grow layers. A method of using this slidable shelving and support apparati and system is also included.

A plant-growing tray (102) comprises an array of cells (108) for containing stabilised media for propagating plants. The tray comprises a tray top (110), and each cell comprises a base (116) and an inclined side wall (114) extending from the base to the tray top. Each cell is configured to receive a stabilised medium, and comprises a plurality of projections (123), positioned around the side wall and facing into the cell, and a plurality of openings (125) defined in the side wall below the projections. The projections (123) are configured in use to support an upper portion of the stabilised medium. In a further aspect, a plant-growing tray for containing stabilised media for propagating plants is configurable in a nesting configuration with a similar tray, and comprises: a tray base configured to support a base portion of a stabilised medium; a support member, configured to support an upper portion of the stabilised medium; and an inclined tray wall connecting the support member to the tray base.

A plant-growing tray comprises a tray top and a plurality of cells extending downwardly from the tray top. Each cell is for containing a substrate for a plant, for the propagation or growth of the plant. Each cell is associated with a catchment area of the tray top, and each catchment area has a sloped surface which, during watering of the plants in the tray, directs water impinging or falling on the catchment area towards the cell.

A gardening appliance includes a liner positioned within a cabinet and defining a grow chamber, and a grow tower is positioned within the grow chamber and includes a module support frame including a plurality of vertical support members a plurality of mounting slots. A grow module defines a support body defining a plurality of apertures for receiving one or more plant pods, the grow module further including a plurality of mounting tabs configured for receipt within the plurality of mounting slots to removably mount the grow module to the module support frame.

A photobioreactor system includes a growing tower tray assembly configured to utilize laminar flow to harvest a plant; a nursery subsystem configured to feed inoculum to the growing tower tray assembly; and a nutrient feeding subsystem configured to feed nutrient media to the growing tower tray assembly.

The disclosure relates to a planter.

A rhizome-growth monitoring device of a clonal plate is provided, including a supporting frame. A first adjustment rack is fixed above a side of the supporting frame, a side end of which is movably connected to a second adjustment rack. A connection sleeve is movably connected to a bottom end of the second adjustment rack. A lifting cylinder is fixed in the connection sleeve. A camera group is fixed to the lifting cylinder through a connection plate. A rhizome growth monitoring sleeve is fixed at a bottom end of the connection plate, and includes an outer sleeve, an inner sleeve, and a radar monitoring head. The outer sleeve is fixed onto the bottom end of the connection plate. The inner sleeve is screwed to an inner side of the outer sleeve. The radar monitoring head is installed in the inner sleeve and close to a bottom surface thereof.

A rhizome-growth monitoring device of a clonal plate is provided, including a supporting frame. A first adjustment rack is fixed above a side of the supporting frame, a side end of which is movably connected to a second adjustment rack. A connection sleeve is movably connected to a bottom end of the second adjustment rack. A lifting cylinder is fixed in the connection sleeve. A camera group is fixed to the lifting cylinder through a connection plate. A rhizome growth monitoring sleeve is fixed at a bottom end of the connection plate, and includes an outer sleeve, an inner sleeve, and a radar monitoring head. The outer sleeve is fixed onto the bottom end of the connection plate. The inner sleeve is screwed to an inner side of the outer sleeve. The radar monitoring head is installed in the inner sleeve and close to a bottom surface thereof.