A growing system is described. The growing system includes a conveyor system, at least one floating tray, a plurality of multifunction beams arranged to contain at least one row, a microclimate exchange system, and a nutriment supply system.

A tray for growing a plant, especially an orchid, with multiple compartments for holding a respective planting pot is provided. The tray comprises at least one fastening means for securing the planting pot. The compartments each have a lower compartment portion designed to receive entirely the planting pot to be inserted, and a respective upper compartment portion comprising the fastening means is formed at least by a compartment wall which is impenetrable to the root system, in particular non-perforated, as well as a system for growing a plant.

A vase for plants or shrubs has a tubular-shaped lateral wall and a base with a first and a second plurality of through-holes, respectively, enabling exit of roots. The lateral wall in transversal section is star-shaped and forms a first plurality of internal cusps and a first plurality of external cusps, each through-hole of the first plurality of through-holes being arranged at a respective one of the external cusps. The vase has a first wall and a second wall which connect one of the internal cusps with an immediately-following one of the external cusps. The first wall and the second wall are mutually contiguous and form there-between an internal angle of less than 180°.

A plant container according to the present invention comprises: a container having a cultivation space therein and having an open upper surface; a guide cover covering the open upper surface of the container and having a plurality of guide openings spaced apart from each other; a medium arranged inside the container and having a plurality of seating openings provided in a number corresponding to the plurality of guide openings; and an input cover covering the upper side of the guide cover and having at least one input opening corresponding to at least one of the plurality of guide openings, wherein the at least one input opening, the one of the plurality of guide openings, and one of the plurality of seating openings are arranged in the vertical direction with respect to one center line.

A system for the fertigation of a plant vessel and method of use for the same is disclosed. The system comprises a grow module containing a plurality of growing trays additionally containing plants, and/or shoots of plants in various stages of development. The growing trays are individually extracted from the grow module via a tray movement system and tray elevator controlled by a control system and precisely placed in a fertigation system, wherein they are aligned over and lowered onto an at least one nozzle which penetrate the plant vessels containing the plants and fertigate them with a combination of water, nutrients, and/or pressurized air. The individual growing tray is then replaced in the grow module and the process is repeated for all growing trays and plant vessels in the grow module.

An automated growing facility for plants, seeds, or seedlings is disclosed. The facility comprises a growing chamber, a fertigation station, a load/unload station, a device such as an automated guided vehicle (AGV) configured to transport grow modules, and a control system configured to control at least one of the grow modules, the fertigation station, the load/unload station, and the AGV. The grow modules are transported from the growing chamber to the fertigation station using the AGV for fertigating plant vessels in growing trays of the grow modules, and the fertigated plants vessels are transported from the fertigation station to the growing chamber using the AGV. Further, the plant vessels are loaded into the growing trays and unloaded from the growing trays at the load/unload station.

A plant growing tray system, and a method of using the same, the system comprising a growing tray including a plurality of tray insert openings configured to accept tray inserts, a pallet stop, and a transfer catch. The system further comprises a plurality of tray inserts comprising a plurality of tray locking points configured to secure each of the plurality of tray inserts within the plurality of tray insert openings, a vessel cavity to hold a plant vessel, a plurality of fertigation holes on the bottom of the vessel cavity configured to receive fertigation needles, and a plurality of plant vessel securement points configured to secure the plant vessel within the vessel cavity.

A plant cultivation apparatus and system including a reservoir and central shaft containing a first and second end, wherein the first end of the central shaft terminates in the central chamber of the reservoir. One or more trays are positioned along the central shaft with variable distances between each tray. The plant cultivation apparatus and system also includes an outer housing member having a plurality of plant-receiving apertures. The outer housing member defines a chamber and has a bottom edge. The bottom edge defines a respective opening, which is configured to contact a reservoir opening. The hydroponic apparatus and system may further include a lighting system mounted above the outer housing member, the lighting system illuminating plants inserted into the plant-receiving apertures to enable the associated plants to photosynthesize in environments exposed to low levels of sunlight.

A green roof planter module includes a planter including a bottom wall and a plurality of side walls that cooperate with one another to define an interior space configured to receive an aggregate and plant matter therein, the bottom wall including at least one aperture extending therethrough, a basin including a bottom wall and a plurality of side walls, wherein the bottom wall of the basin and the side walls of the basin cooperate to define a fluid retention space, wherein the planter is supported above the basin, and a fluid wicking member providing fluid communication from the fluid retention space of the basin to the at least one aperture of the bottom wall of the planter, such that the fluid wicking member is configured to transfer fluid from the fluid retention space of the basin to the aggregate and plant matter located with the interior space of the planter.

A grow module, a plant growing system, and methods for using the same are disclosed herein. The grow module comprises a plurality of tray modules including a light tray over a growing tray. The light tray includes a lighting array and at least one sensor. The growing tray is adapted to hold a plurality of plant vessels. The grow module comprises a machine-readable identification. The grow module is configured to hold the plurality of tray modules in a vertically stacked configuration. The lighting array on the light tray is configured to provide light to the plurality of plant vessels on the growing tray in the grow module directly under said light tray.