An irrigation communicates wirelessly with irrigation control valves. A wireless controller transceiver unit obtains signals from the irrigation controller and transmits these signals wirelessly to a valve transceiver. The irrigation control valves open or close according to the signals received by the valve transceiver. The irrigation system also includes an auxiliary communication device that communicates user commands to the controller transceiver. The user commands are used to create associations between the controller transceiver and each of the valve transceivers. The communication link between the auxiliary communication device and the communication transceiver or the valve transceiver can be an RF communication link such as Bluetooth, a close field communication link such as an inductive communication link, or an optical communication link.

An automated irrigation and/or fertigation apparatus, including a container, a plurality of pumps in the container, and a controller operably connected to each of the plurality of pumps is disclosed. Each of the pumps is configured to provide a unique fertilizer, nutrient and/or micronutrient to irrigation water. The controller is configured to control settings of each of the pumps to provide a predetermined amount of each unique fertilizer, nutrient and/or micronutrient to the irrigation water over a predetermined period of time. Corresponding methods of fertilizing a field and of making the automated irrigation and/or fertigation apparatus are also disclosed.

The present invention is a system for treating land, either to reclaim or optimize the land. Embedded subsurface pipes deliver water to the land. The water may be loaded with soil-treating additives. As water streams from the pipes, it treats the land before passing into a drainage ditch around the periphery of the land. The water is removed from the ditch and recycled, removing contaminants (in reclamation operations) or adding more additives (in optimization operations), before returning to the pipes for another round of treatment, if necessary.

The present invention is a system for treating land, either to reclaim or optimize the land. Embedded subsurface pipes deliver water to the land. The water may be loaded with soil-treating additives. As water streams from the pipes, it treats the land before passing into a drainage ditch around the periphery of the land. The water is removed from the ditch and recycled, removing contaminants (in reclamation operations) or adding more additives (in optimization operations), before returning to the pipes for another round of treatment, if necessary.

The present disclosure is directed to a forward osmosis system/process utilized primarily in conjunction with a subsurface irrigation system/process. Saline wastewater or naturally saline water is treated using forward osmosis membranes that draw at least partially purified water from the wastewater into an osmotic draw solution (draw solution). The resulting diluted osmotic draw solution is then circulated through the subsurface irrigation system including one or more tubular membranes that reject the draw solution while permitting water in the diluted draw solution to pass through.

The present disclosure is directed to a forward osmosis system/process utilized primarily in conjunction with a subsurface irrigation system/process. Saline wastewater or naturally saline water is treated using forward osmosis membranes that draw at least partially purified water from the wastewater into an osmotic draw solution (draw solution). The resulting diluted osmotic draw solution is then circulated through the subsurface irrigation system including one or more tubular membranes that reject the draw solution while permitting water in the diluted draw solution to pass through.

A multi-media irrigation device is disclosed. The multi-media device is a multi-channel emitter device for plant growth. It includes a substrate; a water channel disposed on the substrate, the water channel having a plurality of perforations; a gas channel disposed on the substrate, the gas channel having a plurality of perforations; and at least one further fluid channel disposed on the substrate and having a plurality of perforations. Also disclosed is an integrated, self supporting elevated gas delivery tube and LED light for crop foliage. Lastly, a system for delivery of CO2 gas to light-deprivation operation of cannabis production is disclosed.

A turf management system includes a wireless receiver that is configured to receive respective wireless signals comprising sensor data from wireless sensors positioned in a soil profile at respective depths below a green surface. A control circuit is coupled to the wireless receiver and is configured to determine soil profile conditions at the respective depths below the green surface responsive to the sensor data. The control circuit is coupled to a subsoil environmental control mechanism and is configured to automatically control operation of the subsoil environmental control mechanism responsive to the soil profile conditions at the respective depths below the green surface. The subsoil environmental control mechanism may include an airflow mechanism that is configured to alter airflow below the green surface, and/or a hydronic mechanism that is configured to circulate fluid through a hydronic tubing network below the green surface.

A turf management system includes a wireless receiver that is configured to receive respective wireless signals comprising sensor data from wireless sensors positioned in a soil profile at respective depths below a green surface. A control circuit is coupled to the wireless receiver and is configured to determine soil profile conditions at the respective depths below the green surface responsive to the sensor data. The control circuit is coupled to a subsoil environmental control mechanism and is configured to automatically control operation of the subsoil environmental control mechanism responsive to the soil profile conditions at the respective depths below the green surface. The subsoil environmental control mechanism may include an airflow mechanism that is configured to alter airflow below the green surface, and/or a hydronic mechanism that is configured to circulate fluid through a hydronic tubing network below the green surface.

A soil moisture auto control system which can be used in subsurface irrigation, outer space agricultural farm irrigation, semi-arid and arid agricultural areas irrigation and nutrients addition, as well as auto watering and nutrients addition devices for flower and/or vegetable pots in indoor planting, by an external negative pressure design system responding to soil moisture needs by plants in the agricultural areas by bi-directional flows arrangements to automatically adjust moisture needs for plants.