A thermally regulated enclosure system which includes apparatuses and methods of making and using a thermally regulated enclosure system, including one or more of a vessel having a bottom aperture element which defines a bottom open area, a top aperture element which defines a top open area, one or more stakes detachably fastenable to the peripheral margin of the bottom aperture element of the vessel, and a closure element adjustable in relation to the top aperture element to increase or decrease the top open area.

Disclosed herein are methods and systems for improving performance of sprinkler control systems using aggregations of flow controllers. As an example, to facilitate control of multiple controllers, a system may generate a virtual flow controller by aggregating the two or more flow controllers. A schedule for the virtual controller is set or received and then translated into schedules for the aggregated controllers. In another example, schedules may be set for individual watering zones, which are then translated into watering schedules for flow controllers corresponding to the zones. The system then transmits these schedules to a respective flow controller, which then carries out an irrigation routine according to the schedule.

An irrigation system is provided. The irrigation system includes a reservoir for storing irrigation water, an electrolytic gas generator, a detector, and a control unit. The electrolytic gas generator is in fluid communication with the reservoir to output a first gas and a second gas generated by the electrolytic gas generator to the irrigation water. The detector is arranged in the water reservoir to detect the concentrations of dissolved first gas and dissolved second gas of the irrigation water to obtain dissolved gas concentration information. The control unit electrically connects to the detector and the electrolytic gas generator receives the dissolved gas concentration information and adjusts the voltage applied to the electrolytic gas generator according to the dissolved gas concentration information to control the type of gas generated by the electrolytic gas generator and the concentrations of dissolved first and second gas of the irrigation water.

An irrigation system is provided. The irrigation system includes a reservoir for storing irrigation water, an electrolytic gas generator, a detector, and a control unit. The electrolytic gas generator is in fluid communication with the reservoir to output a first gas and a second gas generated by the electrolytic gas generator to the irrigation water. The detector is arranged in the water reservoir to detect the concentrations of dissolved first gas and dissolved second gas of the irrigation water to obtain dissolved gas concentration information. The control unit electrically connects to the detector and the electrolytic gas generator receives the dissolved gas concentration information and adjusts the voltage applied to the electrolytic gas generator according to the dissolved gas concentration information to control the type of gas generated by the electrolytic gas generator and the concentrations of dissolved first and second gas of the irrigation water.

Water treatment systems including electrically-driven and pressure-driven separation apparatus configured to produce a first treated water suitable for use as irrigation water and a second treated water suitable for use as potable water from brackish or saline water and methods of operation of same.

Water treatment systems including electrically-driven and pressure-driven separation apparatus configured to produce a first treated water suitable for use as irrigation water and a second treated water suitable for use as potable water from brackish or saline water and methods of operation of same.

This invention is directed to a method of growing a plant from the Cannabaceae family, the cultivar or composition produced therefrom, wherein the plant is exposed to artificial lighting of different intensities based on spacing, growth phase, and flowering yield.

This invention is directed to a method of growing a plant from the Cannabaceae family, the cultivar or composition produced therefrom, wherein the plant is exposed to artificial lighting of different intensities based on spacing, growth phase, and flowering yield.

A stack planter reservoir retains a volume of water to be pumped through a hydroponic system. The stack planter reservoir includes a reservoir base, a lateral wall, a lid-receiving lip, and a planter-supporting lid. The reservoir base and the later wall define a storage volume for water. The lid-receiving lip is perimetrically connected to the lateral wall to receive the planter-supporting lid. The planter-supporting lid supports a single planter or a plurality of stacking planters. The planter-supporting lid includes a pump outlet to allow fluid transport from the storage volume to the planter or plurality of stacking planters.

A stack planter reservoir retains a volume of water to be pumped through a hydroponic system. The stack planter reservoir includes a reservoir base, a lateral wall, a lid-receiving lip, and a planter-supporting lid. The reservoir base and the later wall define a storage volume for water. The lid-receiving lip is perimetrically connected to the lateral wall to receive the planter-supporting lid. The planter-supporting lid supports a single planter or a plurality of stacking planters. The planter-supporting lid includes a pump outlet to allow fluid transport from the storage volume to the planter or plurality of stacking planters.