The present disclosure relates to an urban vertical farming system linked directly to a shop. The urban vertical farming system comprises a shop space communicating with a crop cultivation space through a door, and comprises an environment control unit for controlling the environment of the cultivation space, a vertically-movable rack for placing crops cultivated in the cultivation space, a rack transportation means for moving the vertically-movable rack vertically up and down through an area communicating between the cultivation space and the shop space, a pipe system for circulating and controlling the air containing much oxygen and much carbon dioxide in the vegetable cultivation rooms and the mushroom cultivation rooms, respectively, of the cultivation space, and a sustainable recycling means for organic fertilizers manufactured with crops residues from the vegetable cultivation rooms and the mushroom cultivation rooms of the cultivation space and substrate waste after mushroom cultivation.

The specification discloses a hydroponic nutrient aeration and flow control (NAFC) device and system, which both aerates and controls the flow of the hydroponic nutrient solution. The NAFC device has no moving parts. Each NAFC device mixes and aerates the nutrient from the nutrient reservoir with air and/or nutrient from one of the grow tanks. Each NAFC device additionally controls the flow of the aerated nutrient solution to the grow tank and the nutrient reservoir. The vertical position of the end of the nutrient return line in each grow tank may be adjusted to adjust the level of the nutrient solution within the grow tank.

A scalable, hydroponic plant cultivation system that incorporates top-down drip technology, a root misting spray, and a closed loop, lotic nutrient-rich, water-based solution circulation system in a highly oxygenated environment using aeration technology. The hydroponic system starts with a reservoir that is connected at its base to a series of plant containers which is in a closed loop system that pumps nutrient rich solution out from the reservoir to each plant container via an elevated, acequia drip system that provides the nutrient rich solution to the base of the plants, which is then circulated passively down through the root basket and then through the entire system of networked containers and back to the main reservoir. The next element of the hydroponic system has the reservoir connected to a series of pipes and manifolds that run through the upper interior of each plant container to deliver an aerated spray directed at the plant's upper roots. The next element of the hydroponic system is an aeration system that delivers oxygen directly into the nutrient rich water in each container. The final unique aspect of the system is the lightproof cover that covers the top of the root basket and wraps around the base of the stock of the plant to prevent algae growth. The aforementioned elements of the hydroponic system combine to create the optimum environment for what plants need for rapid and vigorous plant growth.

A plant cultivating apparatus includes a body that defines a cultivation chamber, a cultivation bed disposed on the cultivation chamber and configured to move relative to the body, a nutrient storage configured to store nutrient solution, a pipe configured to supply the nutrient solution to the cultivation bed, a bed checker configured to detect movement of the cultivation bed, a level checker configured to detect a level of nutrient solution in the cultivation bed, and a controller configured to receive a signal from the bed checker and the level checker and to adjust the nutrient solution supplied to the cultivation bed. The cultivation bed includes a signal connector that is disposed on one surface of the cultivation bed corresponding to the bed checker and the level checker and that is selectively connected to the bed checker and the level checker according to whether to move the cultivation bed.

A hydroponic growing apparatus may include a housing, a water reservoir, and a lighting system. The housing may include a bottom surface and an open top surface. The apparatus may also include a pump, the pump comprising an inlet and an outlet, and a sprayer coupled to the outlet of the pump. Also, the apparatus may include a support structure configured to fit into an open top surface of the housing. The support structure may define a plurality of openings. The apparatus may include at least one cover plate configured to fit over the support structure in the open top surface of the housing.

A shipping container is fitted to house a vertical hydroponic grow system. The entrance allows wheelchair access. The floor is a skid proof flat and dry design. The ceiling has four side to side rails that can support multiple grow frame movable walls and four movable LED light walls. Each grow frame wall has a plurality of vertically hanging (plastic) grow tubes each with front and rear plant ports. The grow frame walls can be moved to allow wheelchair access for harvesting and replanting without removal of the grow tubes. Each grow frame wall has an integral lower gutter that empties into a catch basin preferably located at an end of the container opposite the entrance. A nutrient reservoir recirculates the nutrient fluid to each grow frame wall on a programmed interval. Ozone and a R/O filter cycle cleans the nutrient fluid on a selected cycle. A seed station can be located at the entrance.

An integrated modular and scalable fogponics crop growth system for cultivating a crop includes an upper growth chamber housing a leafy portion of a crop, a lower growth chamber housing a root portion of the crop, a nutrient tank and dispenser, and an environmental system. The nutrient dispenser is coupled to the nutrient tank holding a nutrient mixture for sustaining the crop. The dispenser atomizes the nutrient mixture into a nutrient fog using a booster pump and a high pressure pump capable of generating approximately 800 PSI to 1500 PSI. The high pressure pump is operatively coupled to a nozzle configured to dispense the atomized nutrient fog, substantially between 6 microns and 15 microns droplet size, into the lower growth chamber. Temperature and humidity are separately controlled in the leaf area.

A vertical tier growing system for growing plants (8). The system includes at least one vertically tiered shelf section (1) secured to and movable along a floor track. Each section (1) has its own means to direct nutrient fluid and light to plants (8) growing on said section (1).

A planting device, a multilayer stereo-planting system using the planting device, and a planting system of a plant factory using the multilayer stereo-planting system are provided. The planting device includes the planting tray and the planting board which can be moved as a whole. The nutrient solution inlet and the nutrient solution outlet are located on the same side of the planting tray. The multilayer stereo-planting system includes the support rack and the nutrient solution supply system installed on the support rack. The planting device can be detachably installed on the support rack as a whole. The planting tray and the planting board of the planting device can be taken out and placed in together, protects the plant seedlings from injuries, and avoids the leakage phenomenon of the nutrient solution.

A method and system for self-contained growth and harvesting of plant and animal foodstuffs and energy generation for terrestrial and non-terrestrial uses. The system can be self-contained and sealed from an ambient atmosphere wherein sufficient oxygen and carbon dioxide levels are maintained (bio-regenerative) to support human life. The system and method may utilize aquaculture and hydroponic plant growth with a digester for converting waste into nutrients. Water may circulate among the digester, aquaculture tanks and hydroponic growth tanks. The method may be scalable to support varying quantities of human life. The system and method may generate energy and consume greater quantities of carbon dioxide than generated. The system may be energy self-sufficient utilizing solar, wind or other energy sources such as generated methane gas.