An accelerated plant-growing system is an apparatus that facilitates plant growth with the application of hydroponics and aeroponics. The apparatus includes a water-leveling distribution assembly, a plurality of planter assemblies, at least one spraying system, a manifold system, and a water supplying system. The water-leveling distribution assembly is the hydroponics application of the apparatus. The at least one spraying system is the aeroponics application of the apparatus. The water-leveling system submerges the roots housed by the plurality of planter assemblies in nutrient-rich water and upholds the plurality of planter assemblies. The at least one spraying system emits nutrient-rich water to the soil. The manifold system delivers nutrient-rich water to the at least one spraying system from the water supplying system. The apparatus further includes a cooler, a light source and a carbon dioxide supply in order to further facilitate plant growth.

An inflatable planting device including a storage tank, a cultivation tank, a field planting tray and a plurality of planting frames is provided. The storage tank has a first air bag. The cultivation tank has a second air bag, and is located on the storage tank. The field planting tray has a mesh air bag defining a plurality of plant holes, and the field planting tray is located on the cultivation tank. The planting frames have a third air bag, and are connected to a periphery of the storage tank, the cultivation tank and the field planting tray through a plurality of connecting holes, where the connecting holes connect the first air bag, the second air bag, the mesh air bag and the third air bag to make the storage tank, the cultivation tank, the field planting tray and the planting frames to form an integrated connection.

A hydroponic growing system uses a plurality of vertically supported pots suspended one above the other, each pot being removably held on a supporting ring attached to a plurality of vertically extending chains, or the like, supported from above. The hydroponic growing system includes a water delivery system which feeds the water to the top-most pot which drains to each next pot and to a bottom reservoir where it may be pumped back into the water delivery system.

An aquaponic garden device is described herein. The device is specifically designed for the homeowners living in urban areas where gardening space is limited.

[Problem] Provided is a compact cultivation device which has a number of management items (parameters) such as air temperature and CO.sub.2 concentration in cultivation space.

[Solution] A compact cultivation device 1 according to the present invention is provided with; an air conditioning sensor 6 which detects the air temperature, the CO.sub.2 concentration, the humidity, or an air current in a cultivation space A; and a nutrient liquid sensor 8 which detects the temperature, the flow rate, the EC, or the pH of a cultivation liquid B. The compact cultivation device 1 is configured to allow cultivation of a plant V while controlling various management items detected by the sensors 6, 8.

The invention relates to a device for growing plants with aeroponics, in the form of a dismountable modular vase composed of superposed modules (4) linked by joining rings (2) and covered by a sealing lid (1) or (21). The modules have a plurality of mouthpieces (5) symmetrically distributed at angular positions, into which the accessories are introduced, such as the rooting basket (6), the micro-greenhouse (22), the seed capsule in the form of a foam cube for germination (23), the support disks (24), (26) or (27), the rod (28) and the grid (29). A tank in two parts (32) and (33) forms a base for the device and comprises an inspection and supply lid (7), a protective grid (8) an on/off switch (9), a connection (10) for the power cable, rollers (30), support legs (31) and an electronic panel (11) that displays information about the level of the nutrient solution, temperature, humidity, timer control and automatic actuation functions of the electric components and electronic circuits. The device actuating components are housed inside, together with the float (15) which stores a mini-generator (16) of nutrient solution nanoparticles, a ventilation pump (17) with an air hose (18), a silencing capsule (19) and a ruler (20) with level sensors.

A hydroponic growing system is disclosed herein. The hydroponic growing system includes a plurality of plant containers, a nutrient reservoir, a nutrient control tower, a plumbing means, a pump, and an overflow tube. The hydroponic growing system is useful for pumping a nutrient solution to the plurality of plant containers from the nutrient reservoir. A method is also disclosed herein.

A vegetable preservation and growing case includes a thermally-insulated case body. The thermally-insulated case is provided therein with at least one vegetable carrying box for use in vegetable growing or preservation. The vegetable carrying box bearing case and the thermally-insulated case body have a pluggable electrical connection and a pluggable water-path connection and allow for disassembly, thus effectively increasing the degree of use convenience.

The present invention is a plant cultivation device. The water tank supplies cultivation water to the cultivation tank via an irrigation conduit. The water tank also suctions cultivation water from the cultivation tank via a water-sucking pipe. The heat-collecting part receives sunlight, and the pressure of air that is heated inside the air-storage part presses the surface of the water inside the water tank. The water tank supplies cultivation water that has been pressed by the air to a culture medium material. The heat-collecting part raises the surface of the water inside the water tank as a result of the heated air being cooled by a decrease in the sunlight. The water tank suctions cultivation water from a bottom section of the cultivation tank.

A system and method for cultivating plants is described. The system may include a tower structure having a vertical series of vessels for holding a netted pot or other container. The system may have a pressurized irrigation system that is in fluid communication with each vessel. The system may further include lamps to provide an adequate light source. The system may also include sensors, monitors and controls to establish and maintain environmental conditions suitable for proper plant growth. The system may further be implemented as a scalable system in which multiple tower structures may be installed into a scaffold system. Sets of towers may be slidably affixed to a scaffold such that the towers may be slid along a track thereby creating easy access to the plants, vessels, lights and the irrigation system. The system may be expanded to include multiple scaffolds affixed to a skeletal frame or compartment interior.