A flexible growcenter includes a mobile container, a behind-the-meter power input system, a power distribution system, a growcenter control system, a climate control system, a lighting system, and an irrigation system. The growcenter control system modulates power delivery to one or more components of the climate control system, the lighting system, and the irrigation system based on unutilized behind-the-meter power availability or an operational directive. A method of dynamic power delivery to a flexible growcenter using unutilized behind-the-meter power includes monitoring unutilized behind-the-meter power availability, determining when a growcenter ramp-up condition is met, and enabling behind-the-meter power delivery to one or more computing systems when the growcenter ramp-up condition is met.

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.

A system and adjustable apparatus for applying CO.sub.2 gas to improve Cannabis production. The system includes upstream and downstream stages or subsystems. The upstream subsystem receives and stores gas, particularly CO2 gas. It monitors the environment of the downstream subsystem, determines when and how to apply gas to plants growing in the downstream system, acquires gas stored in the upstream subsystem, and distributes it to the downstream system. It also has various monitoring, command and control, management, and reporting features. The downstream subsystem includes one or more plant growth areas or plots, gas distribution means, such as gas conduits, tubes or lines from the midstream subsystem, and the high efficiency, adjustable gas applicator, and various sensing and monitoring devices communicatively connected to the upstream subsystem. Also disclosed are systems, apparatus and methods for pest control, humidity control, and odor control.

A system and adjustable apparatus for applying CO.sub.2 gas to improve Cannabis production. The system includes upstream and downstream stages or subsystems. The upstream subsystem receives and stores gas, particularly CO2 gas. It monitors the environment of the downstream subsystem, determines when and how to apply gas to plants growing in the downstream system, acquires gas stored in the upstream subsystem, and distributes it to the downstream system. It also has various monitoring, command and control, management, and reporting features. The downstream subsystem includes one or more plant growth areas or plots, gas distribution means, such as gas conduits, tubes or lines from the midstream subsystem, and the high efficiency, adjustable gas applicator, and various sensing and monitoring devices communicatively connected to the upstream subsystem. Also disclosed are systems, apparatus and methods for pest control, humidity control, and odor control.

A soilless system for high density plant growth includes a greenhouse structure; at least one elongate support member arranged substantially vertically in the greenhouse structure, the support member having a body having a flow channel defined therein; and a plurality of vertically spaced apart receptacles angularly disposed to the vertical axis of the body to receive a plant therein, the receptacles being in fluid communication with the flow channel; a fluid supply system in fluid communication with the flow channel to supply a fluid stream to the flow channel; and a fluid collection system to collect residual fluid that has flowed through the flow channel.

A soilless system for high density plant growth includes a greenhouse structure; at least one elongate support member arranged substantially vertically in the greenhouse structure, the support member having a body having a flow channel defined therein; and a plurality of vertically spaced apart receptacles angularly disposed to the vertical axis of the body to receive a plant therein, the receptacles being in fluid communication with the flow channel; a fluid supply system in fluid communication with the flow channel to supply a fluid stream to the flow channel; and a fluid collection system to collect residual fluid that has flowed through the flow channel.

A plant growing system includes a growth medium preparation unit and a plant growing unit. The growth medium preparation unit includes a supply of water that feeds water through a water treatment unit, a nutrition module, and a reactor sub-system to have the water treated and modified and added with nano-elements and other nutrition components to provide a nutrition formula. The nutrition formula is supplied to the plant growing unit that includes a growing box inside which a tank is provided for receiving and holding the nutrition formula. A plant plate is disposed on the tank and is formed with at least one through opening for receiving and holding a plant. The root of plant is allowed to extend into the nutrition formula inside the tank, while the stem of the plant is growing in a void space above the plant plate and inside the growing box.

The present disclosure relates to a module and system for indoor farming. In some embodiments, an indoor farming module includes a container compartment divided into a grow zone and a control zone, wherein a grow zone comprises a chassis with a plurality of horizontal and vertical frame members configured to support a plurality of carts each carrying a tray with a plurality of plants and wherein the control zone includes an air blowing unit integrated so as to direct air between a drop ceiling and a structural ceiling of the indoor farming module and an air conditioning unit configured to condition an atmosphere in the grow zone by producing cool dry air that is blown into a plenum space located between the drop ceiling and a structural ceiling.

The present disclosure relates to a module and system for indoor farming. In some embodiments, an indoor farming module includes a container compartment divided into a grow zone and a control zone, wherein a grow zone comprises a chassis with a plurality of horizontal and vertical frame members configured to support a plurality of carts each carrying a tray with a plurality of plants and wherein the control zone includes an air blowing unit integrated so as to direct air between a drop ceiling and a structural ceiling of the indoor farming module and an air conditioning unit configured to condition an atmosphere in the grow zone by producing cool dry air that is blown into a plenum space located between the drop ceiling and a structural ceiling.