The present disclosure relates to a plant cultivating apparatus. The plant cultivating apparatus according to an aspect of the present disclosure includes a body configured to have a cultivation chamber therein, a water storage configured to be disposed in the body and store water, a water supply bed configured to be disposed at one side of the cultivation chamber and have a water supply flow path receiving water from the water storage, and a cultivation port configured to be seated on the water supply bed and receive water from the water supply flow path, in which the cultivation port includes a suction member disposed in the cultivation port and suctioning water stored in the water supply flow path, and a medium disposed above the suction member, receiving water from the suction member, and storing nutrients required for plant growth.

A multilevel indoor mobile gutter system for growing vegetation including at least a first level and a second level is provided. Each level may include a first level conveyor and a second level conveyor respectively. A transfer conveyor is operable to convey from the first level to the second level. A plurality of lights are positioned to emit light towards the first level and the second level. At least one gutter is operable to support a plant within. The first level conveyor transports the at least one gutter from the front end to the rear end of the first level, the transfer conveyor transfers the at least one gutter from rear end of the first level to the front end of the second level, and the second level conveyor transports the at least one gutter from the front end to the rear end of the second level.

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.

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.

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 flower water receiver includes a main body formed in a cylindrical shape with an open top to store water, a self-watering module installed on a central portion of a bottom of the main body to form water by condensing moisture in the air, a support formed on a part of the main body in the vicinity of a circumference of the self-watering module to support a circumference of a lower portion of a flower pot placed in an upper portion of the main body, and a wick support member, when the flower pot is placed in the upper portion of the main body, supporting a wick configured to absorb water in the lower portion of the main body and transfer the water to the inside of the flower pot, to be inserted into an inside of a drain hole of the lower portion of the flower pot.

The modular planter assembly incorporates a pedestal structure, a stanchion structure, and a plurality of planting trays. The pedestal structure and the stanchion structure elevate each of the plurality of planting trays such that elevation of any initial planting tray selected from the plurality of planting trays differs from the elevation of any subsequent planting tray selected from the plurality of planting trays. The modular planter assembly is a modular structure. By modular structure is meant that: a) any initially selected planting tray can be substituted for any subsequently selected planting tray; and, b) the number of planting trays contained in the plurality of planting trays is adjustable. The modular planter assembly is a rotating structure. By rotating structure is meant that the cant between the center axis of any initially selected planting tray and the center axis of any subsequently selected planting tray is adjustable.

A hydroponic system and method for growing plants. The system comprises one or more plant support structures, one or more housing membranes, and one or more frames. The one or more plant support structures hold plant matter and have one or more holes. The one or more housing membranes are air-permeable and water-resistant, house a solution and at least a portion of the one or more plant support structures, and have one or more openings in which at least a portion of the one or more plant support structures fit into. The one or more frames support the one or more housing membranes. Methods for growing plants are also provided.

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 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.