An air transport unit comprising a composite board. The composite board comprising an anode layer and a cathode layer of an electrically conducting material. The anode layer and cathode layer are separated by an insulator of an electrically insulating material. The composite board further comprising an electric component in electrical connection with the anode layer and the cathode layer. The air transport unit further comprising a carrier board, wherein the composite board and the carrier board each have a duct forming surface, which carrier board and composite board are arranged so that an air duct forms between the duct forming surfaces.

A water cooling and salt aerosols removal system for cooling roots of a plant includes a salt water module configured to cool a salt water and to remove salt aerosols from an air stream, and a fresh water module configured to further remove salt aerosols from the air stream by using fresh water. The air stream exits the salt water module and enters the fresh water module, and wherein the salt water has a higher content of salt than the fresh water.

A plant growth promoting system according to the present invention makes foliar application of nitric oxide containing a mineral material, an enzymatic material, and a soil microorganism to a root part and leaves of a plant by pressure spraying, makes foliar application of carbonated water containing a plant growth promoter and a moisture fluctuation inhibitor to leaves of the plant by pressure spraying, and applies quantum energy to a round surface and an aerial part of the plant, thus providing the effect of promoting the growth of the plant.

Disclosed is a plant growing system (100), comprising: a plurality of plant growing zones (122); a control apparatus (120) configured to control one or more environmental conditions in each of the plurality of plant growing zones (122); and a receiver (142) configured to receive input data indicating plant type characteristics of a plurality of plant characteristics types to be grown in a plant growing apparatus (120). Also disclosed is a plant growing apparatus (120) configured to grow a plurality of plant types, a method to control a plant growing apparatus (120) configured to grow a plurality of plant types, and a computer program including computer-readable instructions executable to perform a method to control a plant growing apparatus (120) configured to grow a plurality of plant types.

Systems, methods, apparatuses, and computer program products for a greenhouse indoor environment controller based on model predictive control (MPC), which can be integrated into existing greenhouse regulatory systems to optimally maintain critical climatic variables, including artificial lighting levels, CO.sub.2, indoor temperature, and humidity levels within acceptable limits. The objectives of the MPC may be to maximize the rate of crop photosynthesis while optimizing the use of the available water and energy resources, taking into account the unpredictability and intermittent nature of renewable energies and external atmospheric conditions. Accordingly, certain embodiments may facilitate the management of greenhouses by anticipating control actions for a better quality of production. For that, mathematical formulations of the optimal control problem may be described, and the numerical results related to the application of the MPC to case studies are described integrating the effects of greenhouse structural considerations and the influence of climate data on its operation.

A grow pod comprises a container having a sprinkler system, a water reclamation system, a climate control system, a control system, a security system and a plant drying system; and a method of water reclamation for subsequent use within the grow pod.

A flexible growcenter includes a mobile container, a behind-the-meter power input system, a power distribution system, a growcenter control system, a climate control system, a lighting system, and an irrigation system. The growcenter control system modulates power delivery to one or more components of the climate control system, the lighting system, and the irrigation system based on unutilized behind-the-meter power availability or an operational directive. A method of dynamic power delivery to a flexible growcenter using unutilized behind-the-meter power includes monitoring unutilized behind-the-meter power availability, determining when a growcenter ramp-up condition is met, and enabling behind-the-meter power delivery to one or more computing systems when the growcenter ramp-up condition is met.

A plant cultivation system. The system utilizes a trolley conveyor for transport of plants in plant containers. The trolley conveyor uses straight runs of track connected by curved track portions. The straight runs of track of the trolley conveyor are spaced closely together. The trolley conveyor is used to move plant containers to a workshop for planting, fertilization, watering, cultivation, and harvesting of plants or portions thereof, and for packaging of plants or portions thereof for shipment.

The present invention is a plant cultivation device. The water tank supplies cultivation water to the cultivation tank via an irrigation conduit. The water tank also suctions cultivation water from the cultivation tank via a water-sucking pipe. The heat-collecting part receives sunlight, and the pressure of air that is heated inside the air-storage part presses the surface of the water inside the water tank. The water tank supplies cultivation water that has been pressed by said air to a culture medium material. The heat-collecting part raises the surface of the water inside the water tank as a result of the heated air being cooled by a decrease in the sunlight. The water tank suctions cultivation water from a bottom section of the cultivation tank.

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.