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; and covering the mat with a perforated, transparent or semi-transparent cover. Most or all of the apparatus can be biodegradable or removable, and the sand or soil can be similar to indigenous sand or soil. 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 are provided that combine solar technology and agriculture in a symbiotic relationship that optimizes revenue from both sources. An array of reconfigurable solar collector assemblies is deployed in a crop field. As various crops benefit from varying degrees of shade through their development cycles, and are prone to damage from high winds and hail, the array of adaptable, reconfigurable solar collectors is deployed in the crop field and allows for the easy reconfiguration of each solar collector assembly to vary the amount of shade that is applied to the crops below the assembly, and to provide maximum hail and wind protection when necessary.

The present application discloses a production line for afforestation. The technical solution includes at least one mobile platform which has a living area formed thereon, a column disposed at the bottom thereof for forming a sunshade area under the mobile platform for cultivating seedlings, and a walking mechanism installed at the bottom of the column. The production line is convenient for the people to plant trees in the desert.

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; and covering the mat with a perforated, transparent or semi-transparent cover. Most or all of the apparatus can be biodegradable or removable, and the sand or soil can be similar to indigenous sand or soil. 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 cover for plants includes, a frame which has a rectangular top tier of rods, a rectangular bottom tier of rods, four vertical supports which connect the top tier of rods to the bottom tier of rods, and four sides. The cover further includes a side cover which is shaped and dimensioned to cover the four sides of the frame, the side cover has four sides, a top, four top corners, and a bottom. The side cover includes four corner closures disposed at the four top corners. The side cover includes a side closure, and a skirt disposed at the bottom. A top cover is shaped and dimensioned to cover the top of the side cover and the top tier of rods. A crown frame is shaped and dimensioned to fit around the top cover.

A portable shade shelter has a plurality of canopies including at least a first canopy and a second canopy. The first canopy is disposed over the second canopy, and the first canopy is capable of being spaced apart from the second canopy in a vertical direction such that air is capable of flowing between the first canopy and the second canopy. Each of the first canopy and the second canopy includes a plurality of openings configured to permit air and light to pass through the respective first canopy and second canopy.

A method includes receiving a treatment temperature from a user device; positioning a tree within a treatment region of a canopy; flowing a fluid from a hot fluid generating system to the canopy; spraying the fluid from the hot fluid generating system into the treatment region of the canopy; and selectively enabling and disabling a fluid flow from the hot fluid generating system to the canopy to maintain the treatment temperature within the treatment region of the canopy.

Embodiments of the present disclosure provide a humidity and temperature control system for use in the outdoor cultivation of fruits, as typically found in an orchard setting, with the additional aid of a sunshade. Embodiments include a climate control system with an efficient and controlled introduction of water vapor into an outdoor orchard employing a plurality of fogging type nozzles, coupled with an overarching porous solar shade enclosure.

A method for double cropping, with photovoltaic panel arrays mounted on and operating from specialized photovoltaic solar array support structures that are supported above agricultural fields at heights that allow the passage of large mechanized farm equipment to pass beneath. The method of operation is optimized for sun sharing operation in that the solar array support structure and the solar panel array thereon is designed, spaced and computer positioned so as to optimize both the generation of electricity and the agricultural efficiency of the underlying land.