A compound energy co-generation system converts forestry, agricultural, and similar biomass to energy at the source farm. A working fluid reserve at the base is coupled with a boiler inlet. The boiler has a combustion chamber, a vertically rising exhaust stack, and a liquid jacket around the combustion chamber and rising from the working fluid reserve. The liquid jacket receives thermal energy from the combustion chamber and converts a portion of the liquid working fluid into a gas to create a dual-phase working fluid. A reciprocal fluid container, which in one embodiment is a piston and in another is a sealed and insulated container, receives the elevated liquid working fluid. The change in weight drives a power conversion system to convert lowering of the fluid container into electrical energy. Additional ordinarily wasted energy components are employed to perform useful work to improve overall efficiency.

An irrigation device (10) including a solar collector (18) connected to a heating element (14). The heating element is embedded in a hydrated medium and heats this to produce water vapour. A semi-permeable membrane (34) allows the heated water vapour to be used for irrigation, thereby allowing marsh or sea water to be used to irrigate large tracts of arid soil.

Container for aquatic plants, which can be filled with water, the side walls and bottom of which comprise an outer wall and a bottom wall, respectively, in each instance, followed, toward the interior of the container, by an intermediate layer that consists of an insulating material. On the inside of the container, the insulating material is completely covered with a water-tight plastic film, in the manner of a tub, or by a water-tight basin composed of transparent glass. On the bottom of the tub or of the basin and/or in a plant pot situated in the container, there is a plant culture medium that makes growth of aquatic plants possible, and preferably winter-hardy and/or non-winter-hardy aquatic plants are disposed in the container, which is filled with water.

A method of growing plants comprising determining preferential light wavelengths for promoting growth of a plant. The method further comprises constructing one or more light filtering panels arranged to filter natural sunlight or artificial light to produce filtered light comprising the preferential wavelengths. In addition, the method comprises locating one or more plants in a structure constructed at least in part from one or more of the panels. The method also comprises illuminating the structure from outside with natural sunlight or artificial light to pass through the one or more panels and produce the filtered light wherein the filtered light is directed to radiate the plants.

Carbon dioxide molecules can be fixed by growing plants through plant photosynthesis. When the photons that cause the plant synthesis are properly tuned to enhance plant photosynthesis and are generated by a combination of a solar panel of carbon footprint below a threshold and a LED light source of carbon footprint below a threshold and conversion efficiency above a threshold, more CO.sub.2 molecule will be fix by the plant photosynthesis than emitted by the system.

Systems, methods, apparatuses, and computer program products for a greenhouse indoor environment controller based on model predictive control (MPC), which can be integrated into existing greenhouse regulatory systems to optimally maintain critical climatic variables, including artificial lighting levels, CO.sub.2, indoor temperature, and humidity levels within acceptable limits. The objectives of the MPC may be to maximize the rate of crop photosynthesis while optimizing the use of the available water and energy resources, taking into account the unpredictability and intermittent nature of renewable energies and external atmospheric conditions. Accordingly, certain embodiments may facilitate the management of greenhouses by anticipating control actions for a better quality of production. For that, mathematical formulations of the optimal control problem may be described, and the numerical results related to the application of the MPC to case studies are described integrating the effects of greenhouse structural considerations and the influence of climate data on its operation.

A light harvester or collector collects solar radiation from an unshaded location adjacent a growing plant. The light harvester can be either imaging (e.g., parabolic reflectors) or non-imaging (e.g., compound parabolic concentrator). The concentrated solar radiation is projected into a light transmitter that conducts the light through the plant's outer canopy and into the inner canopy to a diffuser which disperses and reradiates the light into the inner canopy. The diffused light transforms a non-productive, potentially leafless zone of the plant into a productive zone so that more fruit can be produced per volume of land surface. The system can prevent transmission of infrared into the inner canopy so that the inner canopy zone is not heated and the amount of water lost to transpiration is reduced. The system can also modify other spectral components to affect plant development and to control pests and diseases.

An atmospheric water generation system comprises water vapor consolidation systems configured to increase the relative humidity of a controlled air stream prior to condensing water from the controlled air stream. The water vapor consolidation system comprises a fluid-desiccant flow system configured to decrease the temperature of the desiccant to encourage water vapor to be absorbed by the desiccant from an atmospheric air flow. The desiccant flow is then heated to encourage water vapor evaporation from the desiccant flow into a controlled air stream that circulates within the system. The humidity of the controlled air stream is thereby increased above the relative humidity of the atmospheric air to facilitate condensation of the water vapor into usable liquid water.

A plant growing apparatus is disclosed that enables users to grow edible vegetation and other plants in all climates and year round. The plant growing apparatus includes a framework, a solar assembly coupled to said framework at a predetermined angle, the solar assembly including at least one photovoltaic panel operable to receive solar energy. A planting bed is coupled to said framework. A lighting assembly is connected to the photovoltaic panel and operably directed to emit light toward said planting bed. The plant growing apparatus includes a watering assembly having a misting conduit in fluid communication with a water source and positioned proximate the photovoltaic panel and defining an aperture and a wiper assembly operably coupled to said at least one photovoltaic panel, said wiper assembly including a pulley system and a wiper blade movable along the photovoltaic panel when said pulley system is actuated.

A method and apparatus for generating solar power in agricultural fields while minimally impacting crop growth and farming efforts, including positioning an elongated solar panel above crops, wherein the elongated solar panel runs generally parallel to longitudinal lines and wherein the elongated solar panel has at least one solar transducing face and an endless edge surrounding and perpendicular to the at least one solar transducing face, automatically pivoting the elongated solar panel such that the at least one solar transducing face is oriented parallel to incident solar rays during predetermined times when plant growth requires incident sunlight, automatically pivoting the elongated solar panel such that the at least one solar transducing face is oriented parallel to the vertical during rain, automatically pivoting the elongated solar panel out of the way of heavy farm equipment, and automatically pivoting the elongated solar panel such that the at least one solar transducing face is oriented perpendicular to incident solar rays at predetermined times when plant growth does not require direct sunlight. The elongated solar panel is positioned sufficiently above crops to give clearance to heavy farm equipment passing therebelow and/or adjacent panels are spaced sufficiently apart such that heavy farm equipment may pass therebetween.