The present invention provides a wind power device capable of effectively suppressing the generation of an imbalance between air and carbon dioxide in a plurality of cultivation portions arranged along a specified direction, and a growing system provided with such a wind power device. The wind power device (100) of the present invention provides wind to objects cultivated in a plurality of cultivation portions (10) disposed along a specified direction (Dm), and the wind power device is provided with a movement unit (120) configured to be capable of reciprocally moving on a movement path (Am) along the specified direction (Dm) and capable of adjusting the period of the reciprocal movement; and at least one blower (131, 132) configured to move along with the movement unit (120).

Vertical growing uses a plurality of shelves to support plants. The system provides nitrogen and light to help grow the plants placed on the shelves. The system also circulates air that is filtered and mixed with the nitrogen before being distributed to the plants. The filters can remove odors from the circulating air.

Vertical growing uses a plurality of shelves to support plants. The system provides nitrogen and light to help grow the plants placed on the shelves. The system also circulates air that is filtered and mixed with the nitrogen before being distributed to the plants. The filters can remove odors from the circulating air.

A method of growing fish and marijuana in a single body of water, includes planting seeds; growing the seeds in a nursery until the plants are 8 inches tall; potting the plants into individual pots; placing the pots with the plants into a float; placing the float into a first bay in a tank with 58 bays and fish in corresponding baskets to be situated under the float with the potted plants; incubating the plants in the first bay and the fish in the corresponding fish basket for 7 days; moving the float and corresponding fish basket into the second bay; adding a second float with another round of potted plants and a second corresponding fish basket into the first bay; progressing the floats and corresponding fish baskets forward to the next bay and adding subsequent floats and corresponding fish baskets into the first bay each 7 days; after 7 days in the 58th bay, harvesting the fish; trimming the plants; moving the plants to a first bay of a flowering stage tank.

A spraying and re-heating vapor reactor includes: a heat preservation boiler; a vapor reaction boiler disposed in the heat preservation boiler; a re-heating conduit communicating the vapor reaction boiler with a device outside the heat preservation boiler, a high heat capacity material being accommodated within the heat preservation boiler, and surrounding the vapor reaction boiler and the re-heating conduit; a heater heating the high heat capacity material; a sprayer disposed in the vapor reaction boiler; and a liquid supplying tube communicating with the sprayer through structure walls of the heat preservation boiler and the vapor reaction boiler, and supplying an external liquid to the sprayer. The sprayer atomizes the external liquid into an atomized liquid absorbing thermal energy from the high heat capacity material and becomes a low-temperature vapor entering the re-heating conduit and being re-heated into a high-temperature vapor. A generator apparatus 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.

Horticulture systems and methods are disclosed. The systems include an air handling rack system comprising frame supply and return plenums, an input diffusion assembly physically supported by and fluidically coupled to the frame supply plenum, and a plant support tray assembly physically supported by and fluidically coupled to the frame return plenum. The input diffusion assembly is configured to direct a supply airflow flowing through the frame supply plenum downwardly from an underside thereof. The plant support tray assembly is positioned below the at least one input diffusion assembly to form an environmental cultivation chamber therebetween. The rack system is configured to direct the supply airflow through the environmental cultivation chamber from the input diffusion assembly to the plant support tray assembly past one or more plants positioned on a support side of the plant support tray assembly and into the frame return plenum as a return airflow.

A cultivation support system for supporting cultivation of a plant includes a growth information acquisition unit configured to acquire information on the growing condition of the plant, a growing condition evaluation unit configured to evaluate the growing condition of the plant on a scale of levels, a work content determination unit configured to determine optimum cultivation work for the growing condition of the plant, a work instruction information creation unit configured to create work instruction information indicating work to be performed by a person engaged in the cultivation of the plant, based on the cultivation work determined by the work content determination unit, and an output unit configured to output the work instruction information created by the work instruction information creation unit.

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.