An air movement system for plant cultivation. An air conditioner receives a gas mixture of air and carbon dioxide, regulates a temperature of the gas mixture, and outputs the gas mixture at the regulated temperature. A first bladeless fan receives the gas mixture output by the air conditioner and supplies the gas mixture as an air flow to a first crop area at a velocity towards an air intake. At least one second bladeless fan assists the air flow from the first crop area to a second crop area so as to maintain the velocity towards the air intake.

An air movement system for plant cultivation. An air conditioner receives a gas mixture of air and carbon dioxide, regulates a temperature of the gas mixture, and outputs the gas mixture at the regulated temperature. A first bladeless fan receives the gas mixture output by the air conditioner and supplies the gas mixture as an air flow to a first crop area at a velocity towards an air intake. At least one second bladeless fan assists the air flow from the first crop area to a second crop area so as to maintain the velocity towards the air intake.

A cannabis growth support apparatus is provided. A cannabis growth support apparatus, for controlling one or more climate systems and monitoring growth of one or more cannabis plants coupled to one or more grow tents, comprising an enclosure housing said one or more climate systems coupled to a power source and a computing device. The computing device having a processor coupled to a computer memory and non-transitory computer readable media and a controller configured to power and regulate the one or more climate systems and a database, coupled to the computing device, for storing climate data from the one or more climate systems. The one or more climate systems is selected from the group consisting of a carbon dioxide enrichment and ventilation system, a humidifier, a dehumidifier, a heater and an air conditioning unit.

A cannabis growth support apparatus is provided. A cannabis growth support apparatus, for controlling one or more climate systems and monitoring growth of one or more cannabis plants coupled to one or more grow tents, comprising an enclosure housing said one or more climate systems coupled to a power source and a computing device. The computing device having a processor coupled to a computer memory and non-transitory computer readable media and a controller configured to power and regulate the one or more climate systems and a database, coupled to the computing device, for storing climate data from the one or more climate systems. The one or more climate systems is selected from the group consisting of a carbon dioxide enrichment and ventilation system, a humidifier, a dehumidifier, a heater and an air conditioning unit.

An indoor gardening appliance includes a liner defining a grow chamber and a grow module rotatably mounted within the grow chamber for receiving a plurality of plant pods. A recirculation duct is in fluid communication with the grow chamber and a fan assembly circulates a flow of air through the recirculation duct and the grow chamber. A gas sensing assembly includes a gas sensor positioned within the recirculation duct for detecting the concentration of a gas within the flow of air and a flow stabilization device at least partially surrounding the gas sensor for reducing pressure fluctuations in the flow of air and improving gas sensor accuracy.

A storage system is disclosed where goods can be stored in containers and the containers are stored in stacks. Above the stacks runs a grid network of rails (e.g., tracks) on which load handling devices can run. To take containers from the stacks and deposit then at alternative locations in the stacks or deposit then at stations where goods may be picked. The framework may be provided with one or more of the following exemplary services: power, power control, heating, lighting, cooling, sensors, and data logging devices. The provision of these services within the framework rather than across the system as a whole, can allow for flexibility in storage whilst reducing cost and inefficiency.

An automatic vertical farming system may include a frame defining at least one growth area and configured to support a plurality of vertical plant growth structures within the at least one growth area. The system may include at least one light, at least one liquid conduit, and at least one gas conduit. The system may include at least one robot disposed on a top side of the frame and movably supported by the frame. The at least one robot may include at least one tool configured to manipulate the plurality of vertical plant growth structures. The system may include a control system including at least one processor configured to automatically control illumination by the at least one light, liquid flow through the at least one liquid conduit, gas flow through the at least one gas conduit, and operation of the at least one robot.

An automatic vertical farming system may include a frame defining at least one growth area and configured to support a plurality of vertical plant growth structures within the at least one growth area. The system may include at least one light, at least one liquid conduit, and at least one gas conduit. The system may include at least one robot disposed on a top side of the frame and movably supported by the frame. The at least one robot may include at least one tool configured to manipulate the plurality of vertical plant growth structures. The system may include a control system including at least one processor configured to automatically control illumination by the at least one light, liquid flow through the at least one liquid conduit, gas flow through the at least one gas conduit, and operation of the at least one robot.

Disclosed herein are control systems and methods for managing and controlling the localized environment for growing plants in an indoor organic environment. The methods and systems provide for optimizing the climate at the localized level beneath the plant canopy to ensure the climate promotes plant growth. The control system controls the environment by monitoring, adjusting, and managing various systems within the indoor growing environment such as an air circulation system, a temperature control system, an irrigation system, a nutrition delivery system, a lighting system, and a sensor system, either individually or in various combinations.

Disclosed herein are control systems and methods for managing and controlling the localized environment for growing plants in an indoor organic environment. The methods and systems provide for optimizing the climate at the localized level beneath the plant canopy to ensure the climate promotes plant growth. The control system controls the environment by monitoring, adjusting, and managing various systems within the indoor growing environment such as an air circulation system, a temperature control system, an irrigation system, a nutrition delivery system, a lighting system, and a sensor system, either individually or in various combinations.