A horticulture facility, including a grow area, a water loop, a nutrient dosing unit configured to dose nutrients to the feed water for the growth area, a hydrogen peroxide dosing unit, configured to introduce a hydrogen peroxide solution into the water loop; a hydrogen peroxide measurement system configured to determine a hydrogen peroxide concentration in the water loop, the hydrogen peroxide measurement system including a sampling unit having a sampling point downstream of the hydrogen peroxide dosing unit, which hydrogen peroxide measurement system is configured to withdraw discrete liquid samples from liquid in the water loop at the sampling point configured to take samples from the water loop and configured to determine a hydrogen peroxide content of a liquid in the water loop; and wherein the horticulture facility includes a controller unit configured to control the hydrogen peroxide content.

A greenhouse according to the present invention includes: a ceiling portion; and in at least a portion of the ceiling portion, a glass sheet with a coating film. The glass sheet with a coating film has a total light transmittance of 90% to 98%, a haze ratio of 20% to 80%, and a hemispherical transmittance of 80% to 90%. When a test is performed according to JIS R 1703-1: 2007 by applying oleic acid to a surface of a coating film and subsequently irradiating the surface with ultraviolet light at an intensity of 1.0 mW/cm.sup.2, a time period from start of irradiation with the ultraviolet light to a point at which a water contact angle on the surface reaches 5° is 24 hours or less.

A greenhouse according to the present invention includes: a ceiling portion; and in at least a portion of the ceiling portion, a glass sheet with a coating film. The glass sheet with a coating film has a total light transmittance of 90% to 98%, a haze ratio of 20% to 80%, and a hemispherical transmittance of 80% to 90%. When a test is performed according to JIS R 1703-1: 2007 by applying oleic acid to a surface of a coating film and subsequently irradiating the surface with ultraviolet light at an intensity of 1.0 mW/cm.sup.2, a time period from start of irradiation with the ultraviolet light to a point at which a water contact angle on the surface reaches 5° is 24 hours or less.

One variation of a method for deploying sensors within an agricultural facility includes: accessing scan data of a set of modules deployed within the agricultural facility; extracting characteristics of plants occupying the set of modules from the scan data; selecting a first subset of target modules from the set of modules, each target module in the set of target modules containing a group of plants exhibiting characteristics representative of plants occupying modules neighboring the target module; for each target module, scheduling a robotic manipulator within the agricultural facility to remove a particular plant from a particular plant slot in the target module and load the particular plant slot with a sensor pod from a population of sensor pods deployed in the agricultural facility; and monitoring environmental conditions at target modules in the first subset of target modules based on sensor data recorded by the first population of sensor pods.

An apparatus for growing plants in a grow room includes an enclosure having a window. The enclosure contains a grow lamp that is arranged to direct light downward through the widow toward the plants. A blower is coupled with the enclosure to drive a flow of air through the enclosure. A gantry apparatus supports the enclosure in the grow room for movement above the plants.

A greenhouse is disclosed having a light-transmitting barrier and a floor surface. The barrier and floor surface are connected to define an enclosure within the greenhouse for plant cultivation. The barrier includes an inner layer delimiting the enclosure and an outer layer. The inner and outer layers are impermeable to air to substantially prevent air from entering the enclosure through the inner layer. The outer layer is spaced apart above the inner layer to define an air passage therebetween. The air passage is in fluid communication with at least one air inlet in a bottom portion of the outer layer and with an air outlet in a top portion of the outer layer. Air within the air passage flows passively from the at least one air inlet to the air outlet upon being heated.

A greenhouse is disclosed having a light-transmitting barrier and a floor surface. The barrier and floor surface are connected to define an enclosure within the greenhouse for plant cultivation. The barrier includes an inner layer delimiting the enclosure and an outer layer. The inner and outer layers are impermeable to air to substantially prevent air from entering the enclosure through the inner layer. The outer layer is spaced apart above the inner layer to define an air passage therebetween. The air passage is in fluid communication with at least one air inlet in a bottom portion of the outer layer and with an air outlet in a top portion of the outer layer. Air within the air passage flows passively from the at least one air inlet to the air outlet upon being heated.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

A process for conditioning the air within a greenhouse comprising transparent walls and a structure including one or more ridge beams as part of a roof of the greenhouse. The process comprises maintaining a pressure difference between an average pressure within the greenhouse and a pressure exterior to the greenhouse, taking in air from the exterior of the greenhouse and mixing this air with air taken from the interior of the greenhouse to obtain conditioned air, distributing the conditioned air via a forced flow to the interior of the greenhouse, and discharging a volume of air from the interior of the greenhouse via openings present in the one or more ridge beams such to maintain the pressure difference.

A process for conditioning the air within a greenhouse comprising transparent walls and a structure including one or more ridge beams as part of a roof of the greenhouse. The process comprises maintaining a pressure difference between an average pressure within the greenhouse and a pressure exterior to the greenhouse, taking in air from the exterior of the greenhouse and mixing this air with air taken from the interior of the greenhouse to obtain conditioned air, distributing the conditioned air via a forced flow to the interior of the greenhouse, and discharging a volume of air from the interior of the greenhouse via openings present in the one or more ridge beams such to maintain the pressure difference.