Novel autonomous self-watering containers for growing plants and soil and hydrogel mixture therefor. The novel self-watering containers are filled with the specific soil and hydrogel mixture and filled with water. The soil and hydrogel mixture absorbs the water and slowly releases it to water the plants planted in the mixture over the next several weeks, requiring no supervision, interaction, or maintenance with the container. The self-watering container and soil and hydrogel mixture save water and labor costs associated with the required frequent maintenance of current plant growing systems.

Novel autonomous self-watering containers for growing plants and soil and hydrogel mixture therefor. The novel self-watering containers are filled with the specific soil and hydrogel mixture and filled with water. The soil and hydrogel mixture absorbs the water and slowly releases it to water the plants planted in the mixture over the next several weeks, requiring no supervision, interaction, or maintenance with the container. The self-watering container and soil and hydrogel mixture save water and labor costs associated with the required frequent maintenance of current plant growing systems.

The present configuration relates to a novelty watering device for use in watering a plant positioned in a planting container, which provides improved and various dripping characteristics.

The present configuration relates to a novelty watering device for use in watering a plant positioned in a planting container, which provides improved and various dripping characteristics.

Provided is a device which can be used to create cavities within the growing media of plant containers to prevent or mitigate against the effects of too much liquid being applied to the growing media. These cavities generally fall into two categories: exfiltration cavities or venting cavities. The exfiltration cavities created by the device allow for the exfiltration of liquid from the growing media of a plant container into the cavities. The venting cavities created by the device provide a space for airflow between the exfiltration cavities and airspace above the growing media in the planting container, so as to facilitate evaporation of the liquid collected in the exfiltration cavity. Also provided is a method for mechanical removal of liquid from the cavities created by the device.

A plant pot cover system, includes a plant pot cover body; a plurality of cover clips; a belt; a watering ring, including a hollow tube with a fertilizer agent inside, a slip tee fitting with an entry aperture, a plurality of adjustable drip fittings, such that the plant pot cover body can be pulled over a plant pot, such that a fertilized water solution drips from the hollow tube into an interior of the plant pot.

A plant pot cover system, includes a plant pot cover body; a plurality of cover clips; a belt; a watering ring, including a hollow tube with a fertilizer agent inside, a slip tee fitting with an entry aperture, a plurality of adjustable drip fittings, such that the plant pot cover body can be pulled over a plant pot, such that a fertilized water solution drips from the hollow tube into an interior of the plant pot.

An apparatus is disclosed for watering plants received in a non-hydroponic substrate, comprising an upwardly open planter for receiving at least one plant with non-hydroponic substrate, the planter having a planting cavity enclosed by a wall and a bottom configured for receiving a plant with the substrate, further comprising a liquid container which is at least partially integrated in the planting cavity or is designed as a separate liquid container which is inserted into the planting cavity from above or is held on an outer wall of the planting cavity, the liquid container being a container which is sealed off from the outside and which has an outlet pipe which opens into a region separated from the planting cavity at a certain distance from the bottom of the planting vessel, the separated region communicating with the planting cavity via at least one connecting opening and communicating with an outer side of the planting vessel via at least one ventilation opening, in such a manner that a liquid volume is established below the outlet tube, which is limited upwardly by a liquid level predetermined by the lower end of the outlet tube, which is located at a level above the bottom of the planting cavity, so that liquid can be discharged from the liquid volume into the substrate via the at least one connecting opening.

An apparatus is disclosed for watering plants received in a non-hydroponic substrate, comprising an upwardly open planter for receiving at least one plant with non-hydroponic substrate, the planter having a planting cavity enclosed by a wall and a bottom configured for receiving a plant with the substrate, further comprising a liquid container which is at least partially integrated in the planting cavity or is designed as a separate liquid container which is inserted into the planting cavity from above or is held on an outer wall of the planting cavity, the liquid container being a container which is sealed off from the outside and which has an outlet pipe which opens into a region separated from the planting cavity at a certain distance from the bottom of the planting vessel, the separated region communicating with the planting cavity via at least one connecting opening and communicating with an outer side of the planting vessel via at least one ventilation opening, in such a manner that a liquid volume is established below the outlet tube, which is limited upwardly by a liquid level predetermined by the lower end of the outlet tube, which is located at a level above the bottom of the planting cavity, so that liquid can be discharged from the liquid volume into the substrate via the at least one connecting opening.

A disclosed vertical planter box assembly includes perimeter walls defining an interior space for holding plants. The perimeter wall includes openings aligned around the interior space. A water basin is provided at a top side for communicating water into the interior space. A drip tray is supported below a bottom side for capturing draining water from the interior space. A plurality of pins extend through the openings and across the interior space to hold the plant structures in place within the interior space.