The present invention is a scalable and re-configurable system for indoor growing. The scalable and re-configurable system for indoor growing is comprised of a plurality of growing sleds, in which each growing sled has a plurality of plant stations. Plants are grown in receptacles on each plant station. The plant station is rotated by a drive system. Each plant station provides irrigation. Each plant station has a forced frame connected to the top of a plant support assembly. A forced frame is used to confine each plant to a known foot-print. This is necessary in indoor growing in order to make the production uniform and efficient.

A method for the automated operation of a greenhouse which has at least one first plant growth room which is operated without artificial lighting and which has at least one second plant growth room which is different from the first plant growth room and which is equipped with artificial light sources for generating artificial light. An associated supply device and an associated greenhouse can be operated automatically.

A lighting system for a vertical farm can include a plurality of modules configured to be stacked and removably coupled physically and electrically to one another by at least one overhead robot. Each of the plurality of modules can include at least one physical and electrical connector. At least some of the modules can include one or more lighting elements.

A growing system is described where plants are grown in containers and the containers are stored in stacks. Above the stacks runs a grid network of tracks on which load handling devices run. The load handling devices take containers from the stacks and deposit them at alternative locations in the stacks or deposit them at stations where goods may be picked out. The containers may be provided with one or more of the following services: power, power control, heating, lighting, cooling, sensing means, data logging means, growing means, water and nutrients.

An automated growing system comprises a plurality of vegetative production lines for moving a plurality of planted growing channels from a first end to a second end of a growing area, a plurality of flowering production lines for moving the channels from the second end to the first end, and a first conveyor belt for moving planted growing channels from the plurality of vegetative production lines to the plurality of flowering production lines. Each production line may comprise a frame, a conveyor assembly configured to receive growing channels, a fertigation delivery line comprising a plurality of regulators spaced therealong for depositing fluid into the growing channels, a drainage trough, and an air supply duct positioned under the conveyor assembly, the air supply duct comprising a plurality of openings therein for delivering conditioned air to plants growing in the growing channels. Each growing channel may comprise a trough having a first end higher than a second end, a flange extending laterally from each of a pair of opposed lateral edges of the trough and having a plurality of leach lines on an upper surface thereof extending a different predetermined distance from the first end toward the second end, and a fertigation receiving structure attached to the first end of the trough and configured to direct fluid falling therein into the leach lines of each flange.

A method and system for moving a plant growing container, wherein the method makes use of a system that includes a cultivation track, a conveying track, a lift and a guide assembly. The method includes the initially moving the plant growing container at the first level along a first direction from a first end of the cultivation track onto the lift next to the first end of the cultivation track. From there, the plant growing container is lowered from the first level to the second level onto the conveying track. To reduce blocking of the system, the guide is movable to a third level higher than the first level. Furthermore, the method further includes guiding the plant growing container by means of moving said guide to said third level once the container has been moved onto the lift.

A method together with enabling apparatuses is disclosed for the rapid controlled growth of vegetable and similar crops in a hydroponic system. The method includes control of light, minimization of exposure to pathogens, control of temperature of ambient air and the water in the system, nutrients, pH and other growth factors such as transfer between ponds as well as specially designed floating flats and related devices.

An automatic and modular system for handling trays (32) used for containing plants or the like to be grown through hydroponic, or aeroponic, or aquaponic farming, comprises a first module (30) with a quadrangular plan and a vertical arrangement delimited by respective vertical supports (31), said first module (30) comprising two lateral zones, each of which includes a plurality of substantially horizontal and overlapping supporting seats or guides (37, 37′) for trays (32), and a central zone in which a vertical tray transfer device (33) operates, slidably along a vertical axis (Z) arranged on a movement means activated by motorization assemblies (34) able to translate said vertical transfer device (33) from a lowered position to a raised position for bringing itself to each tray (32) and vice versa, said vertical transfer device (33) being provided with a resting shelf (33′) for a tray (32) and with a first means adapted to translate along a first horizontal axis (Y) said tray from and towards a respective seat provided inside one of said lateral zones. Said first module (30) further comprises a second means (36) arranged in said central zone in which said elevator device (33) operates, adapted to take in charge a tray (32) when the latter is located on the shelf (33′) of said elevator device (33) and to displace said tray (32) along a second axis (X) horizontal and orthogonal to said first horizontal axis (Y) for performing the direct transfer of said tray (32) towards a further shelf (33′) of a further vertical transfer device (33) of a second module (30) arranged adjacent and connected to said first module.

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 method and a system for growing plants on multilayer principle in mobile gutter farming is described, whereby, in the process of growing plants planted in cultivation gutters, said plants are conveyed in cultivation layers present on top of each other in a cultivation space in a longitudinal direction of the cultivation space in one or opposite directions. The cultivation gutters and the plants contained therein, are treated in the cultivation space by means of a processing arrangement in a cultivation layer-specific manner, whereby the cultivation gutters and the plants contained therein are first of all conveyed by motion elements in each cultivation layer of the cultivation space in the longitudinal direction of the cultivation space in opposite directions and are treated by processing elements in each cultivation layer of the cultivation space separately, in a manner substantially independent of the other cultivation layers.