A plant grower includes a base, an upper cover having a surface parallel to an upper surface of the base, the upper cover being disposed above the base so as to be spaced apart from the upper surface of the base, a plurality of growing panels disposed along the circumference of the upper surface of the base, the plurality of growing panels being rotatably disposed at the base and the upper cover, and a lighting bar extending vertically upwards from the center of the upper surface of the base to the upper cover, the lighting bar emitting light in a direction in which the plurality of growing panels is disposed, and a plurality of growing holders, into each of which a plant is inserted, disposed at one surface of each of the plurality of growing panels.

A flower water receiver includes a main body formed in a cylindrical shape with an open top to store water, a self-watering module installed on a central portion of a bottom of the main body to form water by condensing moisture in the air, a support formed on a part of the main body in the vicinity of a circumference of the self-watering module to support a circumference of a lower portion of a flower pot placed in an upper portion of the main body, and a wick support member, when the flower pot is placed in the upper portion of the main body, supporting a wick configured to absorb water in the lower portion of the main body and transfer the water to the inside of the flower pot, to be inserted into an inside of a drain hole of the lower portion of the flower pot.

A vegetable growth module comprises: a) a rack divided into two or more compartments located vertically one above each other, each compartment being adapted to house a growth tray base; b) an upper segment adapted to house a water-deflecting tub; c) elements adapted to fasten the rack to a vertical wall; and d) water flow and flow-direction elements provided within the rack, to direct the flow of water from one compartment to another compartment located below it.

A vertical farming structure having vertical grow towers and associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled lighting, airflow, humidity and nutritional support. The present disclosure describes a reciprocating cam mechanism that provides a cost-efficient mechanism for conveying vertical grow towers in the controlled environment. The reciprocating cam mechanism can be arranged to increase the spacing of the grow towers as they are conveyed through the controlled environment to index the crops growing on the towers. The present disclosure also describes an irrigation system that provides aqueous nutrient solution to the grow towers.

The disclosure relates to a planter.

An embodiment of the novel and inventive vertical hydroponic system comprises a double-sided system, each side having two sets of double-door tile panels. Each door is mounted on hinges attached at either the right or left sides of an external support frame with the doors opening out from the middle. Each door in this embodiment may support a 6×4 array of novel and inventive tiles, each tile arranged with two columns of 3 pot supports, each such tile capable of supporting 6 grow pots, for a total of 144 grow pots per door. In this embodiment all four doors can support up to 576 grow pots. However, an infinite number of tile variations are possible with the 2×3 array being just one. The doors can be opened during the growth cycle without disconnecting or interrupting the irrigation components which allows for fast and easy harvesting and maintenance. A submersible pump and its control electronics are mounted in the support framework so the system is self-contained. Scheduling software is provided via digital mobile app, which is downloadable from common app sources. The hydroponic system is interconnectible to the internet for remote maintenance and monitoring.

Proposed is a flowerpot including a water supply tube. The flowerpot is configured such that in a state where multiple flowerpots are arranged, adjacent flowerpots are connected to each other by using the water supply tube made of a silicone rubber material having a flexible elastic property to enable water supply, so as to provide a flexible layout between the flowerpots while preventing leakage of water.

Systems and methods for vertical farming that reduce the deployment cost, operational costs of human labor, and overall use of energy intensive processes, such as lighting, heating and cooling, and ventilation, while increasing crop quality and yield. This reduction is achieved through a hybrid system that alternates natural light, temperature, and ventilation sources with system-controlled lighting, temperature, and ventilation means. The system includes a germination module that allows seeds to germinal on a horizontal substrate, a growth module that provides optimal growth conditions to the germinated seed on the substrate in a vertical position, and a dosing module that controls the micronutrient mixture supplied to the growing plants.

A planter includes a wall and a rim formed at an open end portion of the wall. A set of holes is formed through the wall and is disposed on a surface beneath the rim. The surface beneath the rim includes a shape to obscure a view of the hole below the rim.

A fluid dispensing device using only gravity to provide fluid to plant growing medium, for example soil, to the point of either saturation or field capacity. The fluid dispensing device may comprise a mechanism to cease supply of fluid when a threshold amount of fluid in a plant growing medium is detected. The fluid dispensing device may be used to calculate field capacity of different soils. The invention further discloses a gravity powered device for irrigating an area evenly and at a constant rate of irrigation.