Disclosed is an air flow method and system for plant growth and air purification within a grow room to optimize plant production and promote constant growth and quality. The grow room includes a first air mover, a second air mover, and a third air mover. The first air mover is configured to pull air upwards into a first air mover inlet and out of a first air mover outlet oriented away from the first air mover and proximate to the ceiling. The second air mover is configured to pull air into a second air mover inlet and out of the second air mover outlet, moving air towards the floor. The third air mover is to pull air into the third air mover inlet out of the third air mover outlet, moving air away from the third air mover in a horizontal direction towards an opposing wall.

Disclosed is an air flow method and system for plant growth and air purification within a grow room to optimize plant production and promote constant growth and quality. The grow room includes a first air mover, a second air mover, and a third air mover. The first air mover is configured to pull air upwards into a first air mover inlet and out of a first air mover outlet oriented away from the first air mover and proximate to the ceiling. The second air mover is configured to pull air into a second air mover inlet and out of the second air mover outlet, moving air towards the floor. The third air mover is to pull air into the third air mover inlet out of the third air mover outlet, moving air away from the third air mover in a horizontal direction towards an opposing wall.

Provided herein are water and carbon dioxide harvesting systems, as well as methods using such systems, for capturing water and carbon dioxide from surrounding air. The systems and methods use water capture materials to adsorb water from the air and carbon dioxide capture materials to adsorb carbon dioxide from the air. For example, the water and carbon dioxide capture materials may be metal-organic-frameworks. The systems and methods desorb the water in the form of water vapor and the carbon dioxide. The water vapor is then condensed into liquid water. The water and carbon dioxide generated can be used in farming systems, including hydroponics and vertical farming systems.

Provided herein are water and carbon dioxide harvesting systems, as well as methods using such systems, for capturing water and carbon dioxide from surrounding air. The systems and methods use water capture materials to adsorb water from the air and carbon dioxide capture materials to adsorb carbon dioxide from the air. For example, the water and carbon dioxide capture materials may be metal-organic-frameworks. The systems and methods desorb the water in the form of water vapor and the carbon dioxide. The water vapor is then condensed into liquid water. The water and carbon dioxide generated can be used in farming systems, including hydroponics and vertical farming systems.

Systems and methods for managing post-harvest crop quality and pests. A post-harvest monitoring system receives sensor device measurements from sensors deployed within a commodity storage facility. The system analyzes the sensor measurements and, optionally, other data, and provides a user with a representation of the storage facility that includes air flow, temperature, and/or moisture content readouts, along with stored commodity quality and/or stored commodity business metrics predictions concerning infestation level, visible mold, dry matter loss, germination capacity, gas concentration, and estimates of commodity value and profit margin under a variety of post-harvest monitoring system-recommended or user-specified scenarios. Use of the system thus enhances stored commodity quality, marketability and food safety by providing solutions that combat spoilage manifestations and guide end users to efficient pest management.

Systems and methods for managing post-harvest crop quality and pests. A post-harvest monitoring system receives sensor device measurements from sensors deployed within a commodity storage facility. The system analyzes the sensor measurements and, optionally, other data, and provides a user with a representation of the storage facility that includes air flow, temperature, and/or moisture content readouts, along with stored commodity quality and/or stored commodity business metrics predictions concerning infestation level, visible mold, dry matter loss, germination capacity, gas concentration, and estimates of commodity value and profit margin under a variety of post-harvest monitoring system-recommended or user-specified scenarios. Use of the system thus enhances stored commodity quality, marketability and food safety by providing solutions that combat spoilage manifestations and guide end users to efficient pest management.

A plant planting device and a plant planting method. The plant planting device includes at least one plant growing tank, the at least one plant growing tank includes a tank body and a tilt member which is obliquely provided at a bottom of the tank body, configured to support a plant and includes at least one flow guiding element provided on the tilt member; the at least one flow guiding element is arranged to guide liquid for growing the plant to flow from an end to an other end of the tilt member, and the end and the other end of the tilt member are relatively tilted with each other.

A plant planting device and a plant planting method. The plant planting device includes at least one plant growing tank, the at least one plant growing tank includes a tank body and a tilt member which is obliquely provided at a bottom of the tank body, configured to support a plant and includes at least one flow guiding element provided on the tilt member; the at least one flow guiding element is arranged to guide liquid for growing the plant to flow from an end to an other end of the tilt member, and the end and the other end of the tilt member are relatively tilted with each other.

A cabinet for growing plants has a divider. The divider hermetically separates a plant space of the cabinet from a control space of the cabinet. The divider has a plant side, a control side, and electro-magnetic radiation (EMR) emitters, mounted on the plant side of the divider. The EMR emitters are adapted to EMR frequencies primarily at or near visible light. There is a vent in the divider. A fan pulls air through the vent. A microprocessor controls the fan and the EMR emitters.

A cabinet for growing plants has a divider. The divider hermetically separates a plant space of the cabinet from a control space of the cabinet. The divider has a plant side, a control side, and electro-magnetic radiation (EMR) emitters, mounted on the plant side of the divider. The EMR emitters are adapted to EMR frequencies primarily at or near visible light. There is a vent in the divider. A fan pulls air through the vent. A microprocessor controls the fan and the EMR emitters.