This invention pertains to a plant container. The plant container is characterised, essentially, by: a rigid frame (1) formed by at least two mounting supports (2), one for each side of the container, a top ring (3) preferably in a quadrilateral shape, supplemented with lateral and transverse (5) and longitudinal reinforcing beams (4); a soil, water or plant substrate reservoir (6) , supported on said frame; a water deposit (7); and a water transmission system to said substrate.

This invention pertains to a plant container. The plant container is characterised, essentially, by: a rigid frame (1) formed by at least two mounting supports (2), one for each side of the container, a top ring (3) preferably in a quadrilateral shape, supplemented with lateral and transverse (5) and longitudinal reinforcing beams (4); a soil, water or plant substrate reservoir (6) , supported on said frame; a water deposit (7); and a water transmission system to said substrate.

A window planter includes a first compartment including a first sidewall and a second sidewall. The first compartment is configured to house a first group of plants. A second compartment is slidably coupled to the first compartment. The first compartment includes a first outer sidewall. The second compartment is configured to house a second group of plants separated from the first group of plants by the first sidewall of the first compartment. A third compartment is slidably coupled to the first compartment. The third compartment includes a second outer sidewall. The third compartment is configured to house a third group of plants separated from the first group of plants by the second sidewall. At least the first compartment and the second compartment are configured to be secured to a window frame.

The current invention relates to a plant growth and support module comprising (a) a backing (1), (b) a hydroponic substrate (8), wherein said hydroponic substrate (8) comprises an array of holes (9) for receiving a plant and/or a growth medium, (c) an irrigation layer, wherein said irrigation layer comprises a capillary material, and (d) a front (2), wherein said front (2) is connected to said backing (1), enclosing the hydroponic substrate (8) and the irrigation layer, said front (2) comprising an array of openings (4), said array of openings (4) are aligned with the holes of the hydroponic substrate (8), and wherein both the backing (1) and the front (2) comprise glass fibers, and which backing (1) and said front (2) are interconnected by means of an infusible stitching (3). Further aspects of the invention relate to a kit of at least two plant growth and support modules, a green wall, and a method of manufacturing a green wall.

The current invention relates to a plant growth and support module comprising (a) a backing (1), (b) a hydroponic substrate (8), wherein said hydroponic substrate (8) comprises an array of holes (9) for receiving a plant and/or a growth medium, (c) an irrigation layer, wherein said irrigation layer comprises a capillary material, and (d) a front (2), wherein said front (2) is connected to said backing (1), enclosing the hydroponic substrate (8) and the irrigation layer, said front (2) comprising an array of openings (4), said array of openings (4) are aligned with the holes of the hydroponic substrate (8), and wherein both the backing (1) and the front (2) comprise glass fibers, and which backing (1) and said front (2) are interconnected by means of an infusible stitching (3). Further aspects of the invention relate to a kit of at least two plant growth and support modules, a green wall, and a method of manufacturing a green wall.

A flowerpot is disclosed. The flowerpot includes a main body configured to provide a planting space in which an upper portion is open and a central portion is passed through by a through portion in a front and rear direction, a self-watering module installed in the through portion to form water by condensing moisture in the air, and a water supply hole provided on a bottom of the through portion so as to guide the water formed by the self-watering module to the planting space provided in a lower side of the through portion.

A system enabling the recycling of the runoff water and nutrients by a self-wicking mechanism back into the growing media in a controlled and sustained manner. This process of recycling of the runoff provides the plant with optimum hydration, nutrient supply and aeration of the growth media thus eliminating hypoxia and resulting in increased biomass and fruit and/or flower production.

A system enabling the recycling of the runoff water and nutrients by a self-wicking mechanism back into the growing media in a controlled and sustained manner. This process of recycling of the runoff provides the plant with optimum hydration, nutrient supply and aeration of the growth media thus eliminating hypoxia and resulting in increased biomass and fruit and/or flower production.

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 device facilitating water or liquid fertilizer distribution to a plant growth medium by wicking from a tube that accepts a separate and removable liquid reservoir. The tube is closed at the bottom and accepts the outlet of the external reservoir. The tube is inserted into the top surface of the plant growth medium so that the wick emerges from the tube above the top of the plant growth medium and contacts it. As liquid is transferred by the wick, the liquid level in the tube drops below the opening of the reservoir outlet, allowing air to enter the reservoir from the bottom and more water to flow from the reservoir into the tube. The characteristics of the wicks can be adjusted by the user to change the water flow rate and water distribution pattern to accommodate the needs of individual plants.