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 sustained release irrigation apparatus for effective water management. The sustained release irrigation apparatus includes a reservoir, a support structure, an absorbent surface, a water permeable top layer and a top opening on the water permeable top layer for filling water in the reservoir. The support structure is positioned on the reservoir and designed to support a potted plant thereon. The absorbent surface is positioned on the support structure and includes an absorbent opening. The top opening positioned on the water permeable top layer receives water from a water source and fills water into the reservoir. The water collected in the reservoir flows upwards to the water permeable top layer and then reaches the soil inside a pot thereby making water available to the roots of the potted plant without any wastage.

A sustained release irrigation apparatus for effective water management. The sustained release irrigation apparatus includes a reservoir, a support structure, an absorbent surface, a water permeable top layer and a top opening on the water permeable top layer for filling water in the reservoir. The support structure is positioned on the reservoir and designed to support a potted plant thereon. The absorbent surface is positioned on the support structure and includes an absorbent opening. The top opening positioned on the water permeable top layer receives water from a water source and fills water into the reservoir. The water collected in the reservoir flows upwards to the water permeable top layer and then reaches the soil inside a pot thereby making water available to the roots of the potted plant without any wastage.

A top dripping and bottom wicking assembly and method of operation feeds a reservoir that controllably drips liquid nutrient solution from above a plant, and also uses capillary action of a planar wick member to draw the liquid nutrient solution into a plant growing medium and plant roots. The assembly works to controllably drip the liquid nutrient onto the plant through sized and dimensioned drip holes that form in the reservoir, while simultaneously dispersing the liquid nutrient solution through a planar wick member to disperse liquid nutrient solution to a plant growing medium and the roots of the plant. Stakes hold the reservoir above the plant. The wick member is flat and forms a central opening to allow passage of the plant. A plant support member retains the plant in an upright position. The plant support member forms wicking holes to enable passage of liquid nutrients from the wick.

A top dripping and bottom wicking assembly and method of operation feeds a reservoir that controllably drips liquid nutrient solution from above a plant, and also uses capillary action of a planar wick member to draw the liquid nutrient solution into a plant growing medium and plant roots. The assembly works to controllably drip the liquid nutrient onto the plant through sized and dimensioned drip holes that form in the reservoir, while simultaneously dispersing the liquid nutrient solution through a planar wick member to disperse liquid nutrient solution to a plant growing medium and the roots of the plant. Stakes hold the reservoir above the plant. The wick member is flat and forms a central opening to allow passage of the plant. A plant support member retains the plant in an upright position. The plant support member forms wicking holes to enable passage of liquid nutrients from the wick.

A liquid-storing planting device is disclosed. The liquid-storing planting device includes a first box and a second box. The first box includes a plurality of lateral walls and a plurality of first through holes formed on the lateral walls. A tubular body is inserted into the first through hole to connect and communicate two adjacent first boxes. A supporting member is mounted within the first box. A second box is tacked on the first box. A plurality of second through holes are formed on the second box. Each of the second through holes is provided with a liquid absorbing strip. The liquid absorbing strip hangs down to the inside of the first box through the second through hole. The liquid stored in the first box is transferred to the second box by capillary effect of the liquid absorbing strip so as to provide a friendly planting environment.

A liquid-storing planting device is disclosed. The liquid-storing planting device includes a first box and a second box. The first box includes a plurality of lateral walls and a plurality of first through holes formed on the lateral walls. A tubular body is inserted into the first through hole to connect and communicate two adjacent first boxes. A supporting member is mounted within the first box. A second box is tacked on the first box. A plurality of second through holes are formed on the second box. Each of the second through holes is provided with a liquid absorbing strip. The liquid absorbing strip hangs down to the inside of the first box through the second through hole. The liquid stored in the first box is transferred to the second box by capillary effect of the liquid absorbing strip so as to provide a friendly planting environment.

A watering assembly is provided. The watering assembly includes a reservoir body, a support assembly, a wicking assembly, and an inlet assembly. The reservoir body defines an enclosed space. The support assembly is structured to support soil. The support assembly is coupled to the reservoir body. The wicking assembly includes a number of wicking elements; the wicking elements are coupled to at least one of the reservoir body or support assembly. The wicking elements extend from the reservoir enclosed space to a location outside the reservoir enclosed space. The inlet assembly is coupled to the reservoir body and structured to provide fluid communication from a location outside the reservoir enclosed space to the reservoir enclosed space. When the reservoir body, the support assembly, the wicking assembly and the inlet assembly are assembled, the reservoir body, the support assembly, the wicking assembly and the inlet assembly form a contained watering assembly.

A watering assembly is provided. The watering assembly includes a reservoir body, a support assembly, a wicking assembly, and an inlet assembly. The reservoir body defines an enclosed space. The support assembly is structured to support soil. The support assembly is coupled to the reservoir body. The wicking assembly includes a number of wicking elements; the wicking elements are coupled to at least one of the reservoir body or support assembly. The wicking elements extend from the reservoir enclosed space to a location outside the reservoir enclosed space. The inlet assembly is coupled to the reservoir body and structured to provide fluid communication from a location outside the reservoir enclosed space to the reservoir enclosed space. When the reservoir body, the support assembly, the wicking assembly and the inlet assembly are assembled, the reservoir body, the support assembly, the wicking assembly and the inlet assembly form a contained watering assembly.