The present invention provides a bidirectional energy-transfer system comprising: a thermally and/or electrically conductive concrete, disposed in a structural object; a location of energy supply or demand that is physically isolated from, but in thermodynamic and/or electromagnetic communication with, the thermally and/or electrically conductive concrete; and a means of transferring energy between the structural object and the location of energy supply or demand. The system can be a single node in a neural network. The thermally and/or electrically conductive concrete includes a conductive, shock-absorbing material, such as graphite. Preferred compositions are disclosed for the thermally and/or electrically conductive concrete. The bidirectional energy-transfer system may be present in a solar-energy collection system, a grade beam, an indoor radiant flooring system, a structural wall or ceiling, a bridge, a roadway, a driveway, a parking lot, a commercial aviation runway, a military runway, a grain silo, or pavers, for example.

A tower catch mechanism that facilitates loading of vertical grow towers in a vertical farming structure having associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled conditions, such as lighting, airflow, humidity and nutritional support. The present disclosure describes a load conveyance mechanism that transfers grow towers to a loading position where grow towers are loaded onto a select grow line. Each grow line may include a grow tower conveyance system that moves vertically-oriented grow towers to select positions along a grow line. The system may include a tower catch mechanism that registers grow towers in position at the loading position for insertion into a select grow line. In some implementations, the tower catch mechanism can be integrated into other structures of the vertical farming system, such as a gutter basin corresponding to a select grow line.

A tower catch mechanism that facilitates loading of vertical grow towers in a vertical farming structure having associated conveyance mechanisms for moving the vertical grow towers through a controlled environment, while being exposed to controlled conditions, such as lighting, airflow, humidity and nutritional support. The present disclosure describes a load conveyance mechanism that transfers grow towers to a loading position where grow towers are loaded onto a select grow line. Each grow line may include a grow tower conveyance system that moves vertically-oriented grow towers to select positions along a grow line. The system may include a tower catch mechanism that registers grow towers in position at the loading position for insertion into a select grow line. In some implementations, the tower catch mechanism can be integrated into other structures of the vertical farming system, such as a gutter basin corresponding to a select grow line.

Agricultural barns, warehouses, and methods for construction including a floor, walls that include foam wall panels, a wainscot of impact resistant panels at a lower portion of the wall, and a ceiling formed from foam roof panels integrated into the roof truss assembly. Once the floor, walls, and ceiling are assembled, walls and ceiling can be coated over with an abrasion resistant, impact resistant polymeric coating (e.g., akin to a truck-bed liner), tying these structures together in a seamless shell that provides sufficient elasticity to accommodate typical expansion/contraction due to daily and seasonal heating/cooling, humidity changes, etc. The sealed interior envelope allows the interior surfaces to easily be pressure washed daily, or whenever else needed. Such construction is particularly well suited to an agricultural barn or warehouse, where cattle or forklifts may run into the lower portion of the walls, and pressure washing may be a daily need.

A production and consumption system of three-dimensional vertical planting landscape and capable of achieving healthy, low-cost and environmental protection includes an aquatic raising zone, a crop planting zone, an animal raising zone, an insect culturing zone, a food processing zone, a consumption zone, a sport health zone, providing a shopping suggestion list automatically for reference based on a consumer's purchase traceability, and offering a sport suggestion list and a food suggestion list that are suitable for the consumer based on a physiological data so as to allow the consumer to do exercise and control diet, thereby attaining effects of low-cost, environmental protection, super-freshness, high efficiency, high quality of production of vegetables, meat and aquatic products, and functions of purchase, health, shopping, tourism, exercise, fitness and health monitoring.

A production and consumption system of three-dimensional vertical planting landscape and capable of achieving healthy, low-cost and environmental protection includes an aquatic raising zone, a crop planting zone, an animal raising zone, an insect culturing zone, a food processing zone, a consumption zone, a sport health zone, providing a shopping suggestion list automatically for reference based on a consumer's purchase traceability, and offering a sport suggestion list and a food suggestion list that are suitable for the consumer based on a physiological data so as to allow the consumer to do exercise and control diet, thereby attaining effects of low-cost, environmental protection, super-freshness, high efficiency, high quality of production of vegetables, meat and aquatic products, and functions of purchase, health, shopping, tourism, exercise, fitness and health monitoring.

A screen installation comprising a screen cloth assembly (22) with a screen cloth (7) and at least one flat strip (21) fastened to the screen cloth, as well as screen sections (8, 18), to opposite edges of the screen cloth, at least one screen section of which has an undercut chamber (20) and a longitudinal opening (23) that opens into this chamber, wherein the strip is accommodated in the chamber of the at least one screen section so that the screen cloth fastened to it can extend outwards from it through the longitudinal opening of the screen section. The strip (21) is fastened at a distance from the adjacent free edge of the screen cloth (7) in the form of a free screen cloth flap (19). The screen cloth flap extends from the strip and via the longitudinal opening (23) of the at least one screen section (8, 18) outwards from it.

A screen installation comprising a screen cloth assembly (22) with a screen cloth (7) and at least one flat strip (21) fastened to the screen cloth, as well as screen sections (8, 18), to opposite edges of the screen cloth, at least one screen section of which has an undercut chamber (20) and a longitudinal opening (23) that opens into this chamber, wherein the strip is accommodated in the chamber of the at least one screen section so that the screen cloth fastened to it can extend outwards from it through the longitudinal opening of the screen section. The strip (21) is fastened at a distance from the adjacent free edge of the screen cloth (7) in the form of a free screen cloth flap (19). The screen cloth flap extends from the strip and via the longitudinal opening (23) of the at least one screen section (8, 18) outwards from it.

A portable windbreak shelter assembly provides a combination shelter and windbreak which can be moved to a desired position using conventional vehicles typically available on a farm includes a shelter frame having a front, a back, a bottom face, a first lateral side face, and a second lateral side face. The first lateral side face and the second lateral side face extend upwardly from respective opposite edges of the bottom face and meet to define an apex of the shelter frame extending between the front and the back. A covering is coupled to the shelter frame wherein the covering and the shelter frame inhibit wind from passing through the shelter frame to define a sheltered interior space. The shelter frame is movable using conventional farm equipment.

A plug for an air vent which fits into the top aperture of the air vent prevents cement flowing into the vent when a concrete floor is laid. The vent has a peripheral protrusion and a top flange. The plug protrusion snap fits into a concave groove in the top of the vent aperture. The flange extends upward an outward from the vent top so the laid concrete floor has a slot communicating with the vent and the vent top is installed below the floor and thus cannot be easily damaged by storing and removal of produce.