A pot stand is provided that is capable of being simply used, receiving drained water without causing water leakage, reducing manufacturing cost and enables easy disposition of the drained water. The pot stand includes a main body, a water reservoir and a load receiving part. The main body includes an upper surface part that has a drain hole, a side surface part that supports the upper surface part and has a space opened upwardly, and a bottom surface part that is connected to the side surface part. The pot stand further includes an opening that is formed in a part of the side surface part and ribs that are provided in an inner side of the main body. The water reservoir is slidably movable through the opening to be taken in or out from the space. The load receiving part is a standing wall-like shaped and extends from the bottom surface part in the space.

A gully assembly configured for use with like gully assemblies to form part of a horticultural moving gully system, the assembly comprising: (a) an elongate crop holder having spaced apart openings for receiving respective crops to be grown and harvested; and (b) a channel in which water can flow over roots of the spaced apart crops; wherein the assembly is configured to enable adjustment of a distance between the spaced apart openings such that crop density can be varied during a crop growing process.

Hydroponic systems for growing plants, and a corresponding process for line production of the hydroponic systems are provided.

A hydroponic plant production apparatus comprising: a hollow grow tube with a slot formed in the front face of the grow tube, and a matrix media insert composed of two halves, where the media is insertable into the grow tube, allowing plants to be inserted and grown between the two halves of the matrix media insert in the grow tube is provided. Methods for use of a hollow grow tube with a slot formed in the front face of the grow tube, and a matrix media insert composed of two halves, where the media is insertable into the grow tube, allowing plants to be inserted and grown between the two halves of the matrix media insert in the grow tube are also provided.

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 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 greenwall cladding system for the growth of organisms such as plants and fungi on the side of structures, such as internal and external walls of buildings, is provided. Methods for the production of organisms on a greenwall cladding system, such as plants and fungi are also provided herein.

A system for cultivating plants or vegetables, includes a carrier for holding trays accommodating the plants or vegetables, the carrier having an interior formed by a bottom and raised edges extending circumferentially along the bottom to form a container for holding a liquid for cultivating plants or vegetables, and an opening arranged at the bottom; a frame to support the carrier; a supply duct for supplying the liquid towards the carrier, the supply duct arranged at least partly under the carrier; a sprayer device which is at one end fluidly connected to the supply duct and which is at the other provided with a nozzle to direct a flow of liquid to the interior of the carrier; wherein the sprayer device is arranged through the opening of the carrier, the nozzle protruding into the interior of the carrier when the carrier is positioned on the frame.

A hydroponic plant container configured to facilitate the hydroponic growing of a plant wherein the container is configured to provide access to the root ball and other elements disposed therein without engaging the plant. The hydroponic plant container includes a body having a first portion and a second portion. The first portion and the second portion are defined by the same walls and bottom wherein the second portion is offset to the first portion. The first portion and the second portion have an interior volume that is fluidly coupled wherein the interior volume of the second portion is configured to provide a user access to the interior volume of the first portion. The first portion is provided in a preferred shape of round or square. The first portion further includes opposing lip members that are formed on the upper perimeter edge thereof.

A plant cultivating apparatus according to an embodiment of the present disclosure includes a main body, a shelf, a cultivation bed, and a cultivation container. The shelf is disposed in the cultivation space formed in the main body, the cultivation bed is disposed on the shelf, and the cultivation container is seated in the cultivation bed. The cultivation bed includes a water supply part for receiving a predetermined amount of water. In addition, the shelf includes a water level sensor. The water level sensor is positioned vertically below the water supply part to measure an amount of water stored in the water supply part.