Greenhouse comprised of a ridge beam extending some distance above its roof defining two elongated side zones at either side of the ridge beam. The ridge beam is comprised of one or more elongated hollow spaces and with one or more closable openings in both side zones. The openings fluidly connect the exterior of the greenhouse with its interior and may be closed at one side and opened at its other side depending on the direction of the wind.

An apparatus and system for growing plants in a controlled environment comprises an enclosure, at least one basket for receiving plant material to be grown in the apparatus, and at least one cassette for receiving a basket therein. The apparatus further comprises a drive mechanism, said drive mechanism operatively coupled to the at least one basket and/or the at least one cassette, that imparts a drive force to cause the at least one basket to rotate in the at least one cassette and in the enclosure. The apparatus and system also include a climate-control mechanism that may include a light source, a fan, a ventilation system, an air passage, and ductwork. The apparatus and system also include a trough with a sump for drainage of the trough, an intake aperture, a baffle, a closure, an air intake sleeve, and an intake fan.

Techniques for horticulture light are provided. A horticulture light can monitor at least one characteristic of a defined region in which at least one plant is planted in a horticulture environment in which horticulture light bulb is installed, determine at least one action for the horticulture light bulb to perform based on a state of the at least one characteristic and at least one objective of the installation of the horticulture light bulb in the horticulture environment, and execute the at least one action.

Vertical growing uses a plurality of shelves to support plants. The system has an air filtration and ultraviolet (UV) air purification system. The purified and filtered air is mixed with nitrogen, which is directed towards plants. The system can include lights to help grow the plants placed on the shelves. The filters can remove odors from the circulating air.

Disclosed herein is a system for facilitating artificial climate control, in accordance with some embodiments. Accordingly, the system may include a greenhouse enclosure, a condensation assembly, at least one sensor, a water collection compartment, and a processing device. Further, the greenhouse enclosure may include an internal space. Further, the greenhouse enclosure may be configured for generating a greenhouse effect. Further, the condensation assembly may be configured for condensing water vapor present in the interior space. Further, the condensation assembly may include at least one coolant dispenser, a heat exchanger, a coolant sensor, and at least one coolant dispensing actuator. Further, the at least one sensor may be configured for generating at least one sensor data. Further, the water collection compartment may be fluidly coupled with the condensation assembly. Further, the processing device may be communicatively coupled to each of the at least one sensor and the coolant sensor.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer-operated farming superstructure systems (FSS) may be used to produce Cannabis for human consumption with minimal water and environmental impact. A FSS system may comprise modules including liquid distribution and plant growing. A FSS may be configured to be constructed out of a plurality of containerized modules.

The invention concerns a method comprising selecting a grow protocol, selecting an identifier of a container (45), associating the grow protocol with the container identifier, and determining an adjusted target value by applying an adjustment to a target value specified in the growth protocol. The method further comprises controlling an environmental control system (11-13, 27) based on the adjusted target value, obtaining measurement information associated with the container identifier from a device (23), determining a measured plant growth parameter value based on the measurement information, and comparing the measured plant growth parameter value with an expected plant growth parameter value. The method also comprises determining a merit related to a difference between the values and replacing the target value with the adjusted target value and the expected plant growth parameter value with the measured plant growth parameter value in dependence on the merit exceeding a threshold.

The invention concerns a method comprising selecting a grow protocol, selecting an identifier of a container (45), associating the grow protocol with the container identifier, and determining an adjusted target value by applying an adjustment to a target value specified in the growth protocol. The method further comprises controlling an environmental control system (11-13, 27) based on the adjusted target value, obtaining measurement information associated with the container identifier from a device (23), determining a measured plant growth parameter value based on the measurement information, and comparing the measured plant growth parameter value with an expected plant growth parameter value. The method also comprises determining a merit related to a difference between the values and replacing the target value with the adjusted target value and the expected plant growth parameter value with the measured plant growth parameter value in dependence on the merit exceeding a threshold.

Embodiments of the present invention provide hydroponics farming apparatus, and systems including the same. The farming apparatus comprises a frame, a plurality of functional systems, a first plurality of sensors configured to monitor conditions associated with farming of the one or more plants, and one or more modular storage cabinets removably attached to the frame. The one or more modular storages include electronics that are pre-assembled and configured to communicate with one or more of the first plurality of sensors and the plurality of functional systems. The electronics includes a main controller configured to collect data from the first plurality of sensors.

A water supply apparatus in a cabinet includes an outer case defining an outer appearance, an inner case defining a first space therein, and an insulating material disposed between the inner case and the outer case. The water supply apparatus includes a water tank including a tank body configured to store water, and a tank cover configured to open and close the tank body, a tank rail provided in the inner case and configured to allow the water tank to be introduced into or withdrawn from the first space, and a water level detection device configured to be fixedly mounted on the first space, to be in contact with the tank body in a state where the water tank is introduced, and to detect a level of water stored in the tank body.