A plant cultivating apparatus may comprise a cultivating unit, a plurality of cultivating cups, a nutrient bucket, a motor, a temperature adjusting unit, a temperature and humidity sensor, and a control unit. The control unit, which is electrically connected to the motor, the temperature adjusting unit and the sensor, is configured to receive environmental data such as temperature and humidity from the sensor and to turn on/off the motor or/and the temperature adjusting unit according to the received data.

A hydroponic growing method and systems includes receiving sensor data from a plurality of sensors disposed about or around the growing system and comparing the sensor data against standard operating data protocols for operating conditions within the growing system. The growing method and system further detects if an operational risk exists based on the comparison of the sensor data and if the operational safety risk is detected, modify at least one of the plurality of growing components. The growing system may include a cabinet structure along with one or more processing devices.

A greenhouse for underwater cultivation of terrestrial plant species comprising a dome (2) suitable for being filled with air in an underwater environment, provided with an aperture (21) for lower access and made of a material that is impermeable to water and permeable to light, such dome comprising means for restraining to the sea floor, and means for adjusting the level of water/air in the dome itself which must ensure that plant species cultivated in the greenhouse always reside above such level.

Inside such dome a system for the automatic irrigation of the cultivated plants is present comprising a tubular structure (3) on which a plurality of mutually spaced holes (31) is provided, inside which supports are placed for housing and cultivating plant species, irrigation water flowing inside such tubular structure and irrigating such supports in order to achieve a hydroponic culture.

Examples may include a method of cultivating cannabis plants. The method may include placing a first cannabis plant of a plurality of cannabis plants in a first tray of a plurality of trays. The method may also include placing a second cannabis plant of the plurality of cannabis plants in a second tray of the plurality of trays. The first tray may be at a first height. The second tray may be at a second height, and the first height may be different the second height. Furthermore, the method may include flowing a nutrient mixture from a reservoir to the plurality of cannabis plants. In addition, the method may include returning a portion of the nutrient mixture to the reservoir after flowing the nutrient mixture from the reservoir to the plurality of cannabis plants.

A hydroponic cultivation apparatus, a system and a method for facilitating hydroponic cultivation is disclosed. The hydroponic cultivation apparatus includes a reservoir, a plinth, a grow tray with a grow tray lid, and a docking with coupler. The reservoir, placed upon the plinth, is located at a higher position adjacent to the grow tray for optimizing liquid circulation from the reservoir to the grow tray and vice-versa using one or more pipes, a solenoid valve and a pump. The base further includes a dock coupled to the grow tray for providing an electrical connectivity to the grow tray and simultaneously allowing the liquid to flow through the grow tray without being leaked. Further, the apparatus is having a roof which is provided with sources of illumination for providing light required for plant growth.

A soilless system for high density plant growth includes a greenhouse structure; at least one elongate support member arranged substantially vertically in the greenhouse structure, the support member having a body having a flow channel defined therein; and a plurality of vertically spaced apart receptacles angularly disposed to the vertical axis of the body to receive a plant therein, the receptacles being in fluid communication with the flow channel; a fluid supply system in fluid communication with the flow channel to supply a fluid stream to the flow channel; and a fluid collection system to collect residual fluid that has flowed through the flow channel.

A generally planar foundation pad is foamed of a material such as concrete, or the like, and supports a framework defining a plurality of concentric circular paths stacked in a cylindrical array. A plurality of helical water troughs are supported by the framework within each of the circular paths. Water circulation apparatus is provided to selected intermediate portions of the water trough to produce a continuous circulation of water. The circulating water is combined with various nutrients and the nutrient and water solution is filtered as it is circulated. Each helical water trough is formed of multiple vertically stacked layers of the trough. As a result, a great length of water trough is stacked upon a small footprint of land. Each water trough is filled with a plurality of floating growing trays to form a continuous train of growing trays extending down the entire water trough. As the water and nutrient solution flows down each helical water trough, the floating growing trays are carried down the water trough. As the growing trays move, they are continuously removed from the bottom end of the water trough and added at the top.

A ecological vegetable preservation method and an ecological vegetable preservation and growing case. The method includes circularly supplying a nutrient solution to a vegetable in a thermal insulation case body, and regulating temperature, humidity and/or illumination in the thermal insulation case body, so that the vegetable in the thermal insulation case body stays in a growth-retarded state or a slow growth state. Application of the present method and ecological vegetable preservation and growing case allows the growth state of the vegetable to be controlled, thus ensuring to the greatest extent the freshness of the vegetable.

Provided is a method for producing soyasaponins inexpensively and simply without crushing seeds or plant bodies and without performing organic solvent treatment. The method for producing soyasaponins comprises bringing at least a part of a plant body of a leguminous plant into contact with an aqueous solution while culturing or cultivating the plant body using the aqueous solution; and collecting the aqueous solution or separating soyasaponins from the aqueous solution.

Systems, apparatuses and methods for growing marijuana plants, particularly for regulated purposes, for example medical purposes or in some jurisdictions recreational purposes, have automated subsystems with sensors to provide feedback information about system, apparatus and plant growth parameters to one or more controllers so that the one or more controllers can alter one or more parameters to provide optimal conditions for the growing and harvesting of the marijuana plants. In particular aspects, the systems, apparatuses and methods provide for control of odors produced during the growing of marijuana, root management of the marijuana plants and control over important levels of chemicals provided to the plants, for example enzymes and flavor additives.