A method is provided for applying porous carbonaceous particles to soil for purpose of cultivating plants having roots, where at least 95% of the porous carbonaceous particles have a particle size less than or equal to 10 mm. The method incorporates the porous carbonaceous particles into the soil surrounding the plant roots at a depth of between 0-24 inches from the soil surface, where the porous carbonaceous particles are positioned in the area surrounding the roots of the plants at a ratio of between 1:999 to 1:1 porous carbonaceous particles to soil.

A netting system for protecting vine fruit in a fruit zone from destruction by birds in which a net tunnel is formed around the fruit zone away from the fruit.

A method and a system for increasing the degree days in the immediate environment of fruit bearing vines for the cultivation of particular fruit bearing vines, such as non-rustic vinifera variety vines, in unfavourable climatic regions where the degree days is insufficient for the full maturity of the fruit, is described. Rows of the vines are protected in removable shelters which have a removable tarp cover disposed over a support frame structure to shield the rows of vines from the harsh, vine damaging, winter month temperatures while keeping the vines in a controlled temperature environment. Heated liquid circulation conduits are supported in the shelters at predetermined locations and provide controlled heat during the winter months to prevent the vines and the cordon bearing spuds of the vines from damaging cold temperatures. In the early spring the roots are activated early and the tarp is removed and a transparent film sheet covering is substituted to admit sunlight to help activate the vine early to gain degree days. The method and system is also applicable to semi-rustic or rustic wine producing grape vines grown in these climatic regions having degree days down to about 1200.

A method and a system for increasing the degree days in the immediate environment of fruit bearing vines for the cultivation of particular fruit bearing vines, such as non-rustic vinifera variety vines, in unfavourable climatic regions where the degree days is insufficient for the full maturity of the fruit, is described. Rows of the vines are protected in removable shelters which have a removable tarp cover disposed over a support frame structure to shield the rows of vines from the harsh, vine damaging, winter month temperatures while keeping the vines in a controlled temperature environment. Heated liquid circulation conduits are supported in the shelters at predetermined locations and provide controlled heat during the winter months to prevent the vines and the cordon bearing spuds of the vines from damaging cold temperatures. In the early spring the roots are activated early and the tarp is removed and a transparent film sheet covering is substituted to admit sunlight to help activate the vine early to gain degree days. The method and system is also applicable to semi-rustic or rustic wine producing grape vines grown in these climatic regions having degree days down to about 1200.

A system for growing plants includes an elevated track circuit comprising two straight track sections and two arcuate track sections, with the straight track sections each including a cavity. A plurality of wheeled trolleys that each include a wheel configured to roll within the cavities and each include a shaft extending downwardly form the wheel. A drive system is configured to move the wheeled trolleys along the track circuit with the wheeled trolleys connected together by a cable, and with the shafts of the trolleys configured to support plants coupled thereto to selectively move the plants along the track circuit. Uses of the system include for growing produce of vine plants in a lean-and-lower manner, or transporting hanging plants through an irrigation device of the system.

A system for growing plants includes an elevated track circuit comprising two straight track sections and two arcuate track sections, with the straight track sections each including a cavity. A plurality of wheeled trolleys that each include a wheel configured to roll within the cavities and each include a shaft extending downwardly form the wheel. A drive system is configured to move the wheeled trolleys along the track circuit with the wheeled trolleys connected together by a cable, and with the shafts of the trolleys configured to support plants coupled thereto to selectively move the plants along the track circuit. Uses of the system include for growing produce of vine plants in a lean-and-lower manner, or transporting hanging plants through an irrigation device of the system.

A harvesting tumbler apparatus includes first and second spaced apart grating segment retainers, and a tumbler grating including a plurality of resiliently tensionable grating segments connected to the first and second grating segment retainers. The resiliently tensionable grating segments extend from each of the first and second grating segment retainers in a spaced apart circular arrangement. The tumbler apparatus further includes a tension mechanism configured to apply a sufficient tension force to the resiliently tensionable grating segments to cause the grating to form a cylindrical shape. In illustrative embodiments, the resiliently tensionable grating segments may include flexible cord segments.

A harvesting tumbler apparatus includes first and second spaced apart grating segment retainers, and a tumbler grating including a plurality of resiliently tensionable grating segments connected to the first and second grating segment retainers. The resiliently tensionable grating segments extend from each of the first and second grating segment retainers in a spaced apart circular arrangement. The tumbler apparatus further includes a tension mechanism configured to apply a sufficient tension force to the resiliently tensionable grating segments to cause the grating to form a cylindrical shape. In illustrative embodiments, the resiliently tensionable grating segments may include flexible cord segments.

An ecological city system is provided including a core structure and a set of circularly arranged structures having various functions surrounding the core. A plurality of radially arranged transportation structures provide transportation between the circularly arranged structures and the core structure. The ecological city system sustains inhabitant life via a closed loop system for maximizing ecological sustainability, ecological harmony, inhabitant safety, and economic performance and efficiency.

An ecological city system is provided including a core structure and a set of circularly arranged structures having various functions surrounding the core. A plurality of radially arranged transportation structures provide transportation between the circularly arranged structures and the core structure. The ecological city system sustains inhabitant life via a closed loop system for maximizing ecological sustainability, ecological harmony, inhabitant safety, and economic performance and efficiency.