The invention relates to a window for a building structure containing optically transparent and self-cooling coatings on a substrate. The optically transparent and self-cooling coatings has a multi-layered structure including a passive cooling layer, a near-infrared radiation absorption layer and a near-infrared radiation reflecting layer. The optically transparent and self-cooling coatings have a visible light transmittance of more than approximately 70%. In addition, an air temperature under the window under ventilation condition is reduced by at least approximately 2° C., and an air temperature under the window under insulated condition is reduced by at least approximately 8° C.

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.

A control system for controlling humidity in an indoor growing environment is provided, which includes software to control the removal of moisture by using current Vapor Pressure Deficit (VPD) as measured in the indoor air space of a grow room in comparison to a target Vapor Pressure Deficit. The temperature and relative humidity in various areas of the grow room are monitored and used by the software to calculate the current VPD and determine a preferred profile for the target VPD. The control system is configured to maintain consistent VPD with moisture removal by a dehumidifier in response to temperature variations throughout a night/day cycle and through successive growth stages to ensure optimal plant growth and transpiration rates.

An integrated modular and scalable fogponics crop growth system for cultivating a crop includes an upper growth chamber housing a leafy portion of a crop, a lower growth chamber housing a root portion of the crop, a nutrient tank and dispenser, and an environmental system. The nutrient dispenser is coupled to the nutrient tank holding a nutrient mixture for sustaining the crop. The dispenser atomizes the nutrient mixture into a nutrient fog using a booster pump and a high pressure pump capable of generating approximately 800 PSI to 1500 PSI. The high pressure pump is operatively coupled to a nozzle configured to dispense the atomized nutrient fog, substantially between 6 microns and 15 microns droplet size, into the lower growth chamber. Temperature and humidity are separately controlled in the leaf area.

The present disclosure discloses a water recycling type greenhouse, including a greenhouse body; a water collection device is arranged in the greenhouse body; the water collection device is provided with an air inlet and an air outlet; a condensation portion and a reheating portion are arranged in the water collection device; and the water recycling type greenhouse further includes an energy supply system. Air in the greenhouse body can be poured into the water collection device from the air inlet, flow through the condensation portion and the reheating portion in sequence, and finally be discharged into the greenhouse body again from the air outlet. When the heated air is discharged into the greenhouse body again, a decrease of the temperature of the greenhouse is not likely to occur, and normal growth of plants is not easily affected.

A mushroom growing appliance includes a grow chamber defined within a cabinet and a climate control system for regulating the humidity and gas concentrations within the grow chamber. The climate control system includes a water reservoir positioned within the grow chamber for receiving water; a wicking filter positioned at least partially within the water reservoir for wicking the water into the wicking filter; a water supply system comprising a water storage tank that is mounted adjacent the cabinet above the water reservoir, the water storage tank fluidly coupled to the water reservoir through a water supply opening defined through the cabinet; a recirculation fan positioned adjacent the wicking filter for selectively urging a flow of recirculation air through the wicking filter and back into the grow chamber; and a fresh air fan positioned adjacent the wicking filter for urging a flow of fresh air through the wicking filter and into the grow chamber.

The present invention relates to an agricultural film (AF) comprising at least one copolyamide, wherein the copolyamide has been prepared by polymerizing at least one lactam and a monomer mixture (M). The present invention further relates to a process for producing the agricultural film (AF) and to the use of the agricultural film (AF) as mulch film, as silage film, as greenhouse film or as silo film.

Systems and methods of use of chlorine dioxide in controlled environmental agriculture settings and postharvest applications are provided. A method can comprise application of gaseous chlorine dioxide at a level effective to prevent microbial proliferation in a setting containing growing plants. A system can comprise a chemical microorganism control agent dispersal system, an airborne microorganism detection system, and a cultivation environment monitor system.

An indoor gardening appliance includes a grow module rotatably mounted within a liner to at least partially define a first grow chamber and a second grow chamber. A climate control system includes an evaporator plenum housing an evaporator, a fan assembly for urging air through the evaporator plenum, recirculation ducts for independently circulating air through the first grow chamber and the second grow chamber, and ambient duct systems for independently circulating fresh ambient air through the first grow chamber and the second grow chamber. A system of dampers selectively opens or closes each respective recirculation duct and ambient duct system for independent climate control of the first grow chamber and the second grow chamber.

An aquaponic greenhouse is described comprising at least one hydroponic planter, at least one aquatic tank configured to support aquatic life, an irrigation system linking the at least one hydroponic planter and said at least one aquatic tank; a biofilter configured to process waste from the aquatic life to be used to provide nutrients to plants in the at least one hydroponic planter, a geothermal heat exchange system; and a hydronic radiant flooring system.