A planter and stand assembly includes a stand having a sidewall surrounding a hollow region and tapered between a first end of the sidewall and a second end of the sidewall, the stand having a first opening at the first end and a second opening at the second end, the first opening larger than the second opening, and the stand having a first stand support surface at the first end and a second stand support surface at the second end; and a planter having a first planter support surface sized to radially overlap with the first stand support surface and rest thereon in a first configuration in which the first stand support surface faces upward and a second planter support surface sized to radially overlap with the second stand support surface and rest thereon in a second configuration in which the second stand support surface faces upward.

A planter and stand assembly includes a stand having a sidewall surrounding a hollow region and tapered between a first end of the sidewall and a second end of the sidewall, the stand having a first opening at the first end and a second opening at the second end, the first opening larger than the second opening, and the stand having a first stand support surface at the first end and a second stand support surface at the second end; and a planter having a first planter support surface sized to radially overlap with the first stand support surface and rest thereon in a first configuration in which the first stand support surface faces upward and a second planter support surface sized to radially overlap with the second stand support surface and rest thereon in a second configuration in which the second stand support surface faces upward.

An assembly for attachment to a windowpane is disclosed. The assembly includes an adhesive layer attached to the windowpane, a magnetic material attached to the adhesive layer, and a container comprising a magnetically attracted material.

A planter includes an upper part having an inner side wall and a bottom wall that define a chamber for receiving a growing medium and one or more plants, the upper part further having an outer wall radially outward from the inner side wall, the outer wall having a first joining element and the bottom wall having a first connector element; and a lower part having an outer wall radially outward of the inner side wall of the upper part and a bottom wall subjacent the bottom wall of the upper part, the outer wall of the lower part having a second joining element that engages with the first joining element to join the outer walls of the upper and lower parts, and the bottom wall of the lower part having a second connector element to mate with the first connector element.

A planter includes an upper part having an inner side wall and a bottom wall that define a chamber for receiving a growing medium and one or more plants, the upper part further having an outer wall radially outward from the inner side wall, the outer wall having a first joining element and the bottom wall having a first connector element; and a lower part having an outer wall radially outward of the inner side wall of the upper part and a bottom wall subjacent the bottom wall of the upper part, the outer wall of the lower part having a second joining element that engages with the first joining element to join the outer walls of the upper and lower parts, and the bottom wall of the lower part having a second connector element to mate with the first connector element.

An aeroponic planter for use in-ground includes a top strip for receiving plugs that are designed for holding plants. The planter has a rooting chamber capable of enabling aeroponic growth of plant roots, the rooting chamber having a base with a drain. A drain chamber mounts at the base of the rooting chamber for receiving liquid from the rooting chamber. At least one anchor mounted on each of the rooting chamber and the drain chamber for securing the aeroponic planter in soil. In an alternate embodiment, the at least one anchor is integral with the top strip.

The present disclosure relates to a plant cultivating apparatus. The plant cultivating apparatus according to an aspect of the present disclosure includes a body configured to have a cultivation chamber therein, a water storage configured to be disposed in the body and store water, a water supply bed configured to be disposed at one side of the cultivation chamber and have a water supply flow path receiving water from the water storage, and a cultivation port configured to be seated on the water supply bed and receive water from the water supply flow path, in which the cultivation port includes a suction member disposed in the cultivation port and suctioning water stored in the water supply flow path, and a medium disposed above the suction member, receiving water from the suction member, and storing nutrients required for plant growth.

An elongated bag for use as a ready-to-use grow bag. The bag is manufactured as an elongated plastic body with a sealed bottom and a sealable top. The bag includes one or more gussets defined by folds in the bag and a score line for a tear strip in an area sufficiently below the top and above the fill material to allow the bag to lie flat for transportation and deploy into a cylinder for planting. The bag includes drain holes near the bottom of the bag and microperforations along the bag for respiration.

A protective device for use with a hanging planter includes a container that houses a shade. Both the container and the shade are connected to a main shaft that includes a runner. The shade is connected to the runner. When the runner is toward the top end of the container, the shade is housed by the container and is not deployed. When the runner is toward the bottom end of the container, the shade is deployed and extends outward of the container side-to-side.

Aspects of the present invention include a modular growing panel system for attaching vegetation to a surface of a structure. In one aspects, the modular growing panel system includes a growing substrate with a plurality of layers formed into a tile that is rigid and self-supportive of vegetation being grown in the growing substrate and a binder attaching one or more of the tiles to each other and forming the modular growing panel system. In another aspect, the modular growing panel system includes a growing substrate with a plurality of layers formed into a tile that is rigid and self-supportive of vegetation being grown in the growing substrate and a framework for holding and attaching one or more tiles to the structure created from a upper channel and having a slot that corresponds to the depth of the tile and a lower channel and having a slot corresponding to the depth of the tile. Yet another implementation of the modular growing panel system includes a growing substrate with a plurality of layers formed into a tile that is rigid and self-supportive of vegetation being grown in the growing substrate, a framework for holding and attaching one or more tiles to the structure created from a upper channel with an upper flange and having a slot that corresponds to the depth of the tile and a lower channel with a lower flange and having a slot corresponding to the depth of the tile; and upper molding to be affixed to the surface of the structure having a groove disposed to receive the upper flange of the upper channel of the framework and a lower molding to be affixed to the surface of the structure having groove disposed to receive the lower flange of the lower channel of the framework.