A plant growing, transportation, display, and maintenance system including a plant pot and corresponding container having a selectable valve that controls the flow of liquid into and out of the container.

A self-watering planter features wicking devices whose outer tubes feature a skeletal upper structure having a plurality of columns periodically interconnected by rings spanning circumferentially around the wicking material to delimit windows of large area for optimum water seepage to the soil. A flange at the bottom of the tube's skeletal upper portion cooperates with snap features at the top of a lower portion that hangs in the water reservoir to provide snap-fit installation of the wicking devices on a divider wall of a permanently enclosed planter. A soil drainage filtration device features filtration fabric held in a sandwiched state around a drainage opening in the divider wall by one or more mounting plates. In one embodiment, the fabric forms a sack that hangs into the reservoir to suspend a volume of soil therein, whereby the suspended soil serves as wicking agent in the absence of excess rainwater needing drainage.

A self-watering planter features wicking devices whose outer tubes feature a skeletal upper structure having a plurality of columns periodically interconnected by rings spanning circumferentially around the wicking material to delimit windows of large area for optimum water seepage to the soil. A flange at the bottom of the tube's skeletal upper portion cooperates with snap features at the top of a lower portion that hangs in the water reservoir to provide snap-fit installation of the wicking devices on a divider wall of a permanently enclosed planter. A soil drainage filtration device features filtration fabric held in a sandwiched state around a drainage opening in the divider wall by one or more mounting plates. In one embodiment, the fabric forms a sack that hangs into the reservoir to suspend a volume of soil therein, whereby the suspended soil serves as wicking agent in the absence of excess rainwater needing drainage.

A self-feeding watering device comprises a water storage unit, a regulating component and a long nozzle cover, and a water guide string extending out of the water storage unit. The regulating component is engaged to the water storage unit. The cover comprises a top cover for connecting with an external container and a long nozzle tube penetrating through the top cover and communicating with the top cover. The long nozzle tube further penetrates through the regulating component and extends towards a bottom of the water storage unit. The string is partially placed at the bottom of the water storage unit, and partially extends out of the water storage unit. The string allow water to penetrate into outside of the unit, and further guiding the water into the soil for automatic irrigation. The device has a compact structural body, can adjust a watering flow rate by a simplified means.

The present technology is generally directed to modular grow boxes for growing microgreens and other plants. The modular grow boxes generally include a first modular element having a plate and one or more walls extending therefrom to form a chamber, a second modular element having a platform for supporting a growth medium, and a third modular element that can act as a cover and/or base. The first, second, and third modular elements can be assembled in a first configuration that provides a generally enclosed area for growing plants during a germination phase. The first, second, and third modular elements can also be assembled in a second configuration that provides a partially exposed area for growing plants during a post-germination phase. In some embodiments, the modular grow boxes provide a self-contained, self-watering apparatus that is expected to simplify the process of growing microgreens and other plants.

A plant cultivating apparatus according to an embodiment of the present disclosure includes a main body, a shelf, a cultivation bed, and a cultivation container. The shelf is disposed in the cultivation space formed in the main body, the cultivation bed is disposed on the shelf, and the cultivation container is seated in the cultivation bed. The cultivation bed includes a water supply part for receiving a predetermined amount of water. In addition, the shelf includes a water level sensor. The water level sensor is positioned vertically below the water supply part to measure an amount of water stored in the water supply part.

A plant cultivating apparatus according to an embodiment of the present disclosure includes a main body, a shelf, a cultivation bed, and a cultivation container. The shelf is disposed in the cultivation space formed in the main body, the cultivation bed is disposed on the shelf, and the cultivation container is seated in the cultivation bed. The cultivation bed includes a water supply part for receiving a predetermined amount of water. In addition, the shelf includes a water level sensor. The water level sensor is positioned vertically below the water supply part to measure an amount of water stored in the water supply part.

A self-watering system includes a base comprising a reservoir configured to store a defined volume of water and a plurality of wick modules coupled to the base, the plurality of wick modules arranged in an organized pattern and configured to disperse the water from the reservoir. The self-watering system further includes a removable fill tube coupled to the base and configured to receive the water to fill the reservoir, and a removable drain tube coupled to the base and configured to remove the water from the reservoir.

A self-watering system includes a base comprising a reservoir configured to store a defined volume of water and a plurality of wick modules coupled to the base, the plurality of wick modules arranged in an organized pattern and configured to disperse the water from the reservoir. The self-watering system further includes a removable fill tube coupled to the base and configured to receive the water to fill the reservoir, and a removable drain tube coupled to the base and configured to remove the water from the reservoir.

A drainable aerating hydroponics system is used to facilitate the growth of different crops in an efficient and simple manner. The system includes a heat management enclosure, a water reservoir, a perforated basket, a capillary tube, spouts, an aerator, and a drain valve. The heat management enclosure is portable and houses the water reservoir. The water reservoir contains the water and nutrients necessary for the crops. Together with the heat management enclosure, the water reservoir maintains the water under ideal conditions for the crops. The perforated basket supports the growing crops and material necessary for the crops. The capillary tube guides the flow of water and nutrients from the water reservoir to the spouts. The spouts distribute the water flow from the capillary tube to the crops on the perforated basket. The aerator aerates the water within the water reservoir. The drain valve enables the gravity flushing of the water.