There is described a method of growing a plant having at least one light absorbing pigment, the at least one light absorbing pigment absorbing optical energy at absorbing wavelengths. The method generally has illuminating the plant growing light, the growing light having optical energy within at least two spectral regions each encompassing a given wavelength, the given wavelengths being out of tune with the absorbing wavelengths of the at least one light absorbing pigment, the at least two spectral regions being selected from a group consisting of a first spectral region below 400 nm, a second spectral region at about 430 nm, a third spectral region at about 480 nm, a fourth spectral region at about 595 nm, a fifth spectral region at about 640 nm, a sixth spectral region at about 660 nm and a seventh spectral region at about 675 nm.

A growing environment control system includes a house environment control device that controls a surrounding environment of plants under cultivation in an agricultural house, and a parameter management device that creates and provides template parameter information including environment parameter information used by the house environment control device and pertaining to control of the surrounding environment, and identification information pertaining to content or an attribute of the environment parameter information and used for identifying the environment parameter information.

A growing environment control system includes a house environment control device that controls a surrounding environment of plants under cultivation in an agricultural house, and a parameter management device that creates and provides template parameter information including environment parameter information used by the house environment control device and pertaining to control of the surrounding environment, and identification information pertaining to content or an attribute of the environment parameter information and used for identifying the environment parameter information.

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 multi-source ground-to-air heat transfer system is configured to store thermal energy during a cooling/dehumidifcation mode of operation for future use during a heating mode of operation. The multi-source ground-to-air heat transfer system utilizes a ground loop that is configured under an enclosure, such as a greenhouse, and is in thermal communication with a thermal reservoir medium to conduct and store heat. A thermal exchange fluid is pumped through the ground loop and ground heat exchanger and may receive heat from a condenser during a cooling/dehumidification mode of operation and may liberate heat to the evaporator during a heating mode. The enclosure air may receive heat from the heat pump during a heating mode and may liberate heat to the evaporator during a cooling/dehumidification mode. The heat exchange system may employ a heat pump having a reversing valve to change the mode of operation.

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 radiational cooling film providing a variable wavelength which determines a solar heat shielding rate according to the internal temperature of a facility and changes a wavelength conversion section of the film exposed to sunlight to radiate a necessary wavelength according to the growth stage of plants, and a wavelength conversion device and system using the same are provided. The radiational cooling film providing a variable wavelength includes a base layer including a first region and a second region on one surface, a heat barrier layer disposed on a part of the other surface of the base layer, the first region being provided with the heat barrier layer, and the second region being not provided with the heat barrier layer, and a wavelength conversion layer including a plurality of wavelength conversion sections separated from each other in each of the first region and the second region.

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.

A mobile device for storing and supplying multiple liquid fertilizers, comprising a housing, enclosing: two or more storage units, each suitable for storing a liquid fertilizer, wherein each storage unit is provided with a storage unit level measurement system, a storage unit filling system and a storage unit venting system; a safety drain liquid fertilizer storage, comprising at least two separate collectors for the separate containment of spilled liquid fertilizer; a dosing and controlling system; and wherein the housing is equipped with a connection for the input of a water flow, at least two connections for the output of liquid fertilizer, and an output for venting gasses.

A mobile device for storing and supplying multiple liquid fertilizers, comprising a housing, enclosing: two or more storage units, each suitable for storing a liquid fertilizer, wherein each storage unit is provided with a storage unit level measurement system, a storage unit filling system and a storage unit venting system; a safety drain liquid fertilizer storage, comprising at least two separate collectors for the separate containment of spilled liquid fertilizer; a dosing and controlling system; and wherein the housing is equipped with a connection for the input of a water flow, at least two connections for the output of liquid fertilizer, and an output for venting gasses.