The power barn system provides a way to eliminate greenhouse gas (GHG) emissions from livestock. The power barn system seals and traps the methane gas that is emitted from the livestock and converts the methane into electric power and carbon dioxide to enhance plant growth. The power barn system uses PV solar arrays and plastic sheeting to make sealed, airtight structures. The carbon dioxide is provided to one or more sealed greenhouse areas. The plants use the carbon dioxide and release oxygen, thereby completely eliminating greenhouse gas emissions from livestock. The power plant uses the methane at peak times at night while solar panels supply power during the day producing zero emission and 24/7 electricity at better than market rates.

An optical element is provided which comprises a plurality of fluorophores disposed in a medium. The fluorophores have a quantum yield greater than 50% and an absorption spectrum with a maximum intensity at wavelengths less than 400 nm, and emit a spectrum of light having a maximum intensity at wavelengths within the range of 400 nm to 1200 nm. The optical element is at least partially transparent over the visible region of the spectrum. The optical element is especially useful as a window or other optical component of a greenhouse structure.

A solar panel and irrigation arrangement support assembly includes first and second elongated rails each configured to be supported by a roof surface, the first elongated rail including a first longitudinally-extending channel, a plurality of vertical legs each having a first end coupled to at least one of the first and second elongated rails, and a second end, a support assembly coupled to the second end of the plurality of legs and configured to support a solar panel, and an irrigation arrangement that includes an irrigation line located within and extending along the first longitudinally-extending channel of the first elongated rail, and a fluid dispersion member in fluid communication with the irrigation line and configured to be located between the solar panel and plant matter supported by the roof surface such that the fluid dispersion member can provide fluid to the plant matter located directly vertically below the solar panel.

A translucent solar module assembly for integration with a greenhouse having a frame with a plurality of roof supports includes a pair of brackets attachable to each of the plurality of roof supports, a bi-facial solar panel attachable to the pair of brackets, and a pair of reflector rails attachable to each of the plurality of roof supports. A dichroic reflector is attachable to the pair of reflector rails.

A greenhouse facility can include greenhouses such as a first greenhouse and a second greenhouse. The greenhouse facility can also include work units such as a first work unit and a second work unit. The greenhouses and work units can be organized as tenant units that each include at least one greenhouse and at least one work unit. A common roof can cover all the greenhouses and work units. The common roof can include greenhouse canopies and work unit roofs. The greenhouses can be environmentally isolated from the outside environment and from the other greenhouses. The tenant units can be secured from entry via the other tenant units. The greenhouse facility can be formed with shipping containers as architectural elements such as the work units, controlled entry units, etc. The controlled entry units can be used for providing secured access to the greenhouses, work units, and tenant units.

An atmospheric water generation system absorbs water from an atmospheric air stream into a desiccant flowing along a flow path of a closed desiccant circulation loop. To ensure that the desiccant remains within the closed desiccant circulation loop, the atmospheric water generation system encompasses a membrane-based water extraction device that the desiccant flows through. The desiccant flows through the membrane-based water extraction device on a first side of a membrane, and the membrane separates the desiccant from a water-collection flow. Water absorbed into the desiccant passes from the desiccant, through the porous membrane, and into the water-collection flow, at least in part due to differences in temperature and/or pressure characteristics of the water flow and the desiccant flow. Water collected within the water-collection flow is directed to a storage tank for usage.

Provided is a sunlight lighting system used in a greenhouse or a plant factory. The sunlight lighting system converts sunlight into light with a stable illumination direction and a controllable illumination intensity by means of a combination of a controller, a light condenser, a main driving mechanism and an illuminator, so that the sunlight lighting system meets lighting requirements of high-density stereoscopic cultivation frames. A supporting greenhouse is further comprised, where a facade or a top is provided with a light through hole. A main optical axis of the sunlight lighting system passes through the light through hole. A supporting lighting method is further comprised, which can obtain a better lighting effect with fewer steps.

The present invention relates to a photovoltaic facility (1) comprising a solar tracker (2) and at least one square or rectangular photovoltaic panel (3) mounted on the solar tracker (2), this solar tracker (2) enabling the inclination of the photovoltaic panel (3) to be varied with respect to the horizontal, so that two opposite edges of the photovoltaic panel, referred to as horizontal edges (31), are always horizontal whatever the inclination of the photovoltaic panel (3).

This facility is characterised in that it comprises at least one gutter (4) for recovering rainwater, in that this gutter (4) is mounted along one of the two horizontal edges (31) of the photovoltaic panel (3) using at least two anchoring devices (5), to which it is suspended, so that it can oscillate under the action of its own weight, about a horizontal axis of rotation (Y-Y′), so as to remain horizontal whatever the inclination of the photovoltaic panel (3).

The present disclosure relates to a sunlight converting device including a wavelength converting film using a wavelength conversion material such as a quantum dot or an inorganic phosphor. More particularly, the present disclosure provides a sunlight converting device including a wavelength converting film using a wavelength conversion material, which can optimize plant growth and provide improved plant quality by installing a wavelength converting film on which a wavelength conversion material is applied so as to be converted into a predetermined wavelength and output to a greenhouse (glasshouse), a vinyl house or a microalga culture facility, varying the sunlight irradiation area of the wavelength converting film, and supplying light of various wavelengths required for species of plant including microalgae or growth cycles thereof.

The present disclosure provides an agrivoltaic forecasting modeling system that can assess solar power yields and crop yield produced by an agrivoltaic system. The system may include a weather information providing component providing weather information; an agrivoltaic facility comprising a cultivation area for a crop and a structure with a solar panel and being adjacent to the crop and being operated based on setting conditions and the weather information; a power generation calculation component calculating the amount of power generation of the agrivoltaic power generation facility based on the weather information; a crop yield information calculation component calculating yield information of the crop based on the weather information and the setting conditions; and an optimal condition selection component calculating the optimal conditions for agrivoltaic system's solar power yields and crop yields based on the yield information, and therefore the crops can experience the various irradiance changes caused by the solar panel.