A hydroponic growing system is presented. The system can include multiple growing trays in a vertical arrangement, where a pump supplies the top-most tray and each lower tray is supplied by the overlying tray, and where the plumbing elements for supply and drainage are arranged to one side of the system. The system includes variations to support different crop types within the same system, including removable growing structures for root vegetable, microgreens and supports for vining crops. The system can monitor and adjust the nutrients and other features of the systems water profile to concurrently group multiple crops in differing developing stages.

The present disclosure discloses an integrated regulation and control device and method for light, heat and water in a greenhouse, and a greenhouse. The regulation and control device includes a shading and condensing plate arranged at a top of a chamber of a greenhouse; a cavity is formed in the shading and condensing plate; the shading and condensing plate is further provided with a water inlet and a water outlet which are communicated to the cavity; the regulation and control device further includes an energy supply system and a heat dissipation device; the energy supply system can inject a cold source into the cavity through the water inlet; the energy supply system can also transport a heat source to the heat dissipation device; the heat dissipation device can dissipate heat of the heat source into the greenhouse.

The present disclosure discloses an integrated regulation and control device and method for light, heat and water in a greenhouse, and a greenhouse. The regulation and control device includes a shading and condensing plate arranged at a top of a chamber of a greenhouse; a cavity is formed in the shading and condensing plate; the shading and condensing plate is further provided with a water inlet and a water outlet which are communicated to the cavity; the regulation and control device further includes an energy supply system and a heat dissipation device; the energy supply system can inject a cold source into the cavity through the water inlet; the energy supply system can also transport a heat source to the heat dissipation device; the heat dissipation device can dissipate heat of the heat source into the greenhouse.

A method of preparing a flowering plant product in hypobarically- and hypoxically-controlled atmospheres is disclosed. The method includes providing a simulated high-altitude controlled atmosphere (SHACA) room having a chamber, a plant support structure disposed within the chamber, and a microclimate control system operable to establish and maintain within the chamber a simulated high-altitude environment having an oxygen (O2) partial pressure of less than 20 kRa and, optionally, an overall pressure of less than 97 kPa. The method also includes disposing a flowering plant on the plant support structure, and exposing the flowering plant to the simulated high-altitude environment within the chamber. A simulated high-altitude CA room for cultivating and processing flowering plants in a hypobaric and hypoxic atmosphere is also provided.

A system and method for generating high-yield plant production is disclosed. The system includes a container, a growing station, and a monitoring system. The growing station includes vertical racks, a lighting system, an irrigation system, a climate control system, and a ventilation system. The monitoring system monitors all of the systems in the growing station, as well as the environment within the container, to provide real-time data and alerts to a user.

A system and method for generating high-yield plant production is disclosed. The system includes a container, a growing station, and a monitoring system. The growing station includes vertical racks, a lighting system, an irrigation system, a climate control system, and a ventilation system. The monitoring system monitors all of the systems in the growing station, as well as the environment within the container, to provide real-time data and alerts to a user.

An apparatus for cultivating plants may include a cabinet forming a space in which plants may be cultivated; a door connected to the cabinet to open or close the space; at least one bed disposed in the space; at least one seed package separably seated on the at least one bed and having a medium including seeds of plants and nutrient solution; and a light assembly to radiate light to the at least one seed package disposed on the at least one bed. The at least one bed may include an upper bed on which the at least one seed package may be seated and a bottom bed on which the upper bed may be seated and that forms a water collecting portion that stores water, and the at least one seed package may be supplied with the water stored in the water collecting portion.

An osmotic food production system designed to produce fruits, vegetables, and freshwater from urine or saltwater. In some embodiments the osmotic food production system also produces oxygen. In some embodiments, the osmotic food production system is portable and capable of transporting on a vehicle capable of space travel. Embodiments of the present invention can be used to address the existing problems of food production, waste disposal/utilization, oxygen generation, and water conservation in an efficient way to allow for prolonged space travel or colonization of distant planets and moons.

An apparatus for cultivating plants and a refrigerator according to a embodiment of the present disclosure includes a cabinet including a cultivation chamber with an open front; a door configured to be rotatably coupled to the cabinet by hinges to open and close the cultivation chamber and having a see-through window through which the interior of the cultivation chamber is capable of being seen; a bed provided to be introduced or withdrawn inside the cultivation chamber and on which a plurality of pods in which plants are cultivated are seated; a pair of side plates forming both sides of the machine room having a front which is opened at the lower portion of the cabinet; a pair of coupling frames configured to extend in the front and rear direction along the side plate in the machine room and to protrude further forward than the open front surface of the machine room; and a supporter coupled to the forward protruding portion of the pair of coupling frames and supported on the ground, in which the supporter is positioned below the door in a state where the door closes the cultivation chamber to prevent the cabinet from being overturned.

An apparatus for cultivating plants according an embodiment of the present disclosure includes a cabinet forming a cultivation space; a machine room configured to be positioned below the cabinet; a bed configured to be mounted inside the cultivation space; a water tank configured to supply water to the bed; and a drain member configured to be positioned between the cultivation space and the machine room; wherein the bed includes a water collecting portion configured to store water; and a water supply portion configured to supply water to the water collecting portion, wherein an end portion of a water supply pipe configured to supply water from the water tank to the water supply portion is positioned above the water supply portion, and wherein the drain member is positioned below the water supply portion.