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.

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.

Disclosed is a facility for cultivating plants in a confined atmosphere, including: a container having a length, a width and an inner volume, at least one portion of the inner volume forming a cultivation compartment; a system for supporting vertical cultivation supports; vertical cultivation supports attached to the support system; a vertical lighting system including light sources for illuminating the plants and arranged facing the vertical cultivation supports; and a mobility system for either moving the lighting system or for simultaneously moving two vertical cultivation supports, or both.

A plant surface structure includes an array of plastic base elements, each base element having a deck carried by a series of pillar elements. The deck is provided with at least a number of the pillar elements having an open top end in the deck. A membrane is placed over the deck and is provided with slits or cut-outs or water permeable elements, such that they open into at least some of the open top ends of the pillar elements. A growing medium is provided on the membrane and a growing medium is provided in the pillar elements, the growing medium in the pillar elements preferably being in fluid contact with the growing medium on the membrane.

A control system includes a shell including an enclosed area, one or more carts moving on a track within the enclosed area, an air supplier within the enclosed area, one or more vents connected to the air supplier and configured to output air within the enclosed area, and a controller. The controller is configured to: identify a plant on the one or more carts; determine a humidity recipe for the identified plant; control the air output from the one or more vents based on the humidity recipe for the identified plant; receive an image of the plant the in one or more carts captured by the imaging sensor; and update the humidity recipe for the plant based on the captured image of the plant.

A cultivation floor system has a floor on which plant containers are to be placed. The system includes a watertight basin and a water-permeable structure in the basin, which structure has a permeable top cloth which forms the top side of the floor on which plant containers are placed. The structure includes one or more water-retaining layers. A watering installation supplies water so that water is available for the plants in the plant containers. A perforated film is placed between the permeable top cloth on the one hand and the one or more water-retaining layers on the other hand, which perforated film is made of impermeable film material which is provided with distributed perforations in such a manner that the film reduces the free evaporation surface for water from the one or more water-retaining layers.

A seedling growing system includes: a cargo transport container provided with heat insulating treatment; a movement robot for moving on a path in the cargo transport container; seedling growing tray racks including a multi-shelf germination rack for holding, until germination, a seedling growing tray on which seeds are sown, a multi-shelf seedling growing rack for holding a seedling growing tray on which seedlings have germinated, and a multi-shelf shipment rack for holding a seedling growing tray for shipping grown seedlings; and an arm or table provided to the movement robot and capable of transferring each seedling growing tray between the movement robot and each of the multi-shelf germination rack, multi-shelf seedling growing rack, and the multi-shelf shipment rack.

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.

An apparatus for use in indoor agriculture is provided, the apparatus comprising a plurality of elongate supports (6) connected to at least one common manifold (8a, 8b). Each elongate support (6) within the plurality of elongate supports (6) comprising: a main body (12) having a first side; at least one inlet (16) in fluid communication with the at least one common manifold (8a, 8b); a plurality of outlets (14); and a channel within and extending along substantially the length of the main body (12) between the at least one inlet (16) and the plurality of outlets (14). The at least one common manifold (8a, 8b) is configured to allow gas to flow into the at least one inlet (16) of the plurality of elongate supports (6), wherein the apparatus is configured such that during use, gas may flow from the common manifold (8a, 8b) to the at least one inlet (16) of each elongate support (6) within the plurality of elongate supports (6), through the channel of each elongate support (6) and out of the plurality of outlets (14) of each elongate support (6), such that a uniform flow of gas is provided adjacent the first side of the main body (12) during use.

A cultivation floor system with a floor includes a watertight basin with a watertight groundsheet, a water-permeable structure in the basin, and a permeable top sheet which lies substantially horizontally over the water-permeable structure and forms the top side of the floor on which plant containers are optionally placed. The basin has a water-barrier structure which protrudes above the floor and delimits the compartment which is present on the floor. The water-barrier structure includes a horizontal beam with a top side, a water-barrier profile with a bottom side, and fastening means which fasten the water-barrier profile to the horizontal beam. The top side of the beam is substantially level with the top side of the floor formed by the permeable top sheet. The bottom side of the water-barrier profile is pulled onto the top side of the horizontal beam while clamping the watertight groundsheet and the permeable top sheet.