Provided is a flower pot generating little root rot by controlling a water supply rate for a relatively long period of time even using a simple structure regardless of its size.

The flower pot includes: an outer pot body; an inner pot body housed in the outer pot body with a gap as a water supply portion; a vertical position changeable member provided in a predetermined place to connect the outer pot body and the inner pot body; a flange provided on an upper end surface of the sidewall of the inner pot body; and a sealing portion formed of an elastic member and provided between the flange and the upper end surface of the sidewall of the outer pot body, in which water stored in the water supply portion is supplied to the inner pot body through a nonwoven fabric member.

An irrigation system for vertical planting systems has at least one water storage container arranged vertically above the vegetation body, and at least one capillary-active water conductor arranged therein, which protrudes from the water storage container and protrudes into the vegetation body.

An irrigation system for vertical planting systems has at least one water storage container arranged vertically above the vegetation body, and at least one capillary-active water conductor arranged therein, which protrudes from the water storage container and protrudes into the vegetation body.

A green roof planter module includes a planter including a bottom wall and a plurality of side walls that cooperate with one another to define an interior space configured to receive an aggregate and plant matter therein, the bottom wall including at least one aperture extending therethrough, a basin including a bottom wall and a plurality of side walls, wherein the bottom wall of the basin and the side walls of the basin cooperate to define a fluid retention space, wherein the planter is supported above the basin, and a fluid wicking member providing fluid communication from the fluid retention space of the basin to the at least one aperture of the bottom wall of the planter, such that the fluid wicking member is configured to transfer fluid from the fluid retention space of the basin to the aggregate and plant matter located with the interior space of the planter.

The present invention concerns a hydro planter comprising an inner container which can accommodate a substrate, an absorption medium and an outer container. The inner container has one or more grids that enable liquid to filter from the inner container to the outer container. The absorption medium has at least one conductive element that is located in the substrate within the inner container and the conductive element is also located in the outer container, and the absorption medium also has a flattened portion which extends with the inner container. Finally, the outer container has two or more legs which enable the outer container to be supported on a surface and which form a gap through which air or water can flow, and the hollow interior of each leg forms a tank for storing a liquid, inside of which the lower portion of the conductive element is received. Thus, the hydro planter can receive plants, store liquid, supply said liquid to the plants, avoid spills, be adapted to concrete surfaces, to green flat roofs, to a modular system comprising a plurality of hydro planters, or a combination thereof; said hydro planter can improve thermal insulation and have a configuration that facilitates the transportation thereof, and can be manufactured with recyclable materials and low manufacturing costs.

The present invention concerns a hydro planter comprising an inner container which can accommodate a substrate, an absorption medium and an outer container. The inner container has one or more grids that enable liquid to filter from the inner container to the outer container. The absorption medium has at least one conductive element that is located in the substrate within the inner container and the conductive element is also located in the outer container, and the absorption medium also has a flattened portion which extends with the inner container. Finally, the outer container has two or more legs which enable the outer container to be supported on a surface and which form a gap through which air or water can flow, and the hollow interior of each leg forms a tank for storing a liquid, inside of which the lower portion of the conductive element is received. Thus, the hydro planter can receive plants, store liquid, supply said liquid to the plants, avoid spills, be adapted to concrete surfaces, to green flat roofs, to a modular system comprising a plurality of hydro planters, or a combination thereof; said hydro planter can improve thermal insulation and have a configuration that facilitates the transportation thereof, and can be manufactured with recyclable materials and low manufacturing costs.

A method and apparatus for cultivating vegetation at an arid location includes rooting immature vegetation in a mat combined with a super absorbent polymer (SAP) and, in embodiments, fertilizer, sand, and/or soil; placing the mat at the arid location; covering the mat with a perforated, transparent or semi-transparent cover; collecting urine in a water purification system; and providing purified water extracted from the urine to the mat. A water barrier can be placed below the mat. The cover can be placed on or suspended above the mat. SAP, seeds, and/or additional water barriers can be placed between mats in a stack. The opacity of the cover can be increased to emulate shade from natural vegetation. A water distribution system can be included for continued support of the vegetation, and can include a water reservoir and/or at least one solar still.

A method and apparatus for cultivating vegetation at an arid location includes rooting immature vegetation in a mat combined with a super absorbent polymer (SAP) and, in embodiments, fertilizer, sand, and/or soil; placing the mat at the arid location; covering the mat with a perforated, transparent or semi-transparent cover; collecting urine in a water purification system; and providing purified water extracted from the urine to the mat. A water barrier can be placed below the mat. The cover can be placed on or suspended above the mat. SAP, seeds, and/or additional water barriers can be placed between mats in a stack. The opacity of the cover can be increased to emulate shade from natural vegetation. A water distribution system can be included for continued support of the vegetation, and can include a water reservoir and/or at least one solar still.

A multiple plant container self-watering system comprising a frame supporting multiple grow pots, the multiple grow pots comprising at least a primary grow pot and a secondary grow pot; a primary container at a first elevation on said frame wherein said primary grow pot rests on a primary wick of the primary reservoir pot, and a plurality of secondary containers, each of the plurality of secondary containers being at a different elevation and comprising a secondary grow pot resting on a secondary wick of the secondary reservoir pot; whereby the primary container and the plurality of secondary containers are fluidly connected by means of the tubing and configured to allow for substantially similar dry-down time.

A multiple plant container self-watering system comprising a frame supporting multiple grow pots, the multiple grow pots comprising at least a primary grow pot and a secondary grow pot; a primary container at a first elevation on said frame wherein said primary grow pot rests on a primary wick of the primary reservoir pot, and a plurality of secondary containers, each of the plurality of secondary containers being at a different elevation and comprising a secondary grow pot resting on a secondary wick of the secondary reservoir pot; whereby the primary container and the plurality of secondary containers are fluidly connected by means of the tubing and configured to allow for substantially similar dry-down time.