An automated water control device comprises a rotatable housing that can be incrementally positioned to control flow of water over an upper or weir edge of the housing. The device is installed at a control point in an impoundment area, such as a settling pond. The housing is selectively rotated to raise and lower the height of the weir edge to a target gate height. Automatic control is provided for operation of the device by a controller communicating with an actuator. A system of the invention includes one or more water control devices and the controller. A method of the invention includes controlling flow of water from an impounded water source by use of the automated water control device. Manual or semi-automated embodiments are also disclosed.

An automated water control device comprises a rotatable housing that can be incrementally positioned to control flow of water over an upper or weir edge of the housing. The device is installed at a control point in an impoundment area, such as a settling pond. The housing is selectively rotated to raise and lower the height of the weir edge to a target gate height. Automatic control is provided for operation of the device by a controller communicating with an actuator. A system of the invention includes one or more water control devices and the controller. A method of the invention includes controlling flow of water from an impounded water source by use of the automated water control device. Manual or semi-automated embodiments are also disclosed.

A fiber block system suitable for check dam applications is described that comprises a central section flanked by two shorter wing sections. Each section comprises a fiber block enclosed in a sleeve of mesh. The fiber block, mesh, and ties can be made of coir fibers.

Apparatus, systems and methods for irrigating lands are disclosed. In one example, an irrigation system is disclosed. The irrigation system includes a gate and a microcontroller unit (MCU). The gate is configured for adjusting a water flow for irrigating a piece of land. The MCU is configured for controlling the gate to adjust the water flow based on environmental information related to the piece of land.

Apparatus, systems and methods for irrigating lands are disclosed. In one example, an irrigation system is disclosed. The irrigation system includes a gate and a microcontroller unit (MCU). The gate is configured for adjusting a water flow for irrigating a piece of land. The MCU is configured for controlling the gate to adjust the water flow based on environmental information related to the piece of land.

The present invention relates to a flood irrigation apparatus. The apparatus comprises a headgate in communication with a body of water. The body of water can be a pond or a reservoir, for example. The apparatus further comprises a conduit securely connected to the headgate and in fluid communication with the headgate, wherein the flow of water within the conduit is regulated by the operation of the headgate. The apparatus further comprises an exit chamber securely connected to the conduit and in fluid communication with the conduit. The exit chamber comprises a plurality of vertical bricks disposed on the floor of the exit chamber. The vertical bricks facilitate the trapping of the silt and debris on the floor of the exit chamber in order to provide substantially silt-free water for irrigation.

The present invention relates to a flood irrigation apparatus. The apparatus comprises a headgate in communication with a body of water. The body of water can be a pond or a reservoir, for example. The apparatus further comprises a conduit securely connected to the headgate and in fluid communication with the headgate, wherein the flow of water within the conduit is regulated by the operation of the headgate. The apparatus further comprises an exit chamber securely connected to the conduit and in fluid communication with the conduit. The exit chamber comprises a plurality of vertical bricks disposed on the floor of the exit chamber. The vertical bricks facilitate the trapping of the silt and debris on the floor of the exit chamber in order to provide substantially silt-free water for irrigation.

A surge irrigation system includes a main inlet pipe configured to be coupled to a source of pressurized water. The main inlet pipe is coupled to a flow meter for the purpose of improving furrow irrigation. The system further includes two independent, valve-actuated and controlled pipe arm segments extending from the main inlet pipe. One of the pipe arm segments extends toward a first irrigation zone in a field, and the second pipe arm segment extends toward the second irrigation zone in the field. The system further includes water advance sensors for the purpose of improving a surge irrigation program for an improved autonomous and parameter-setting operation. Additionally the controller, sensor and interface use radio communication.

Disclosed is a control system for a water network. The control system includes a plurality of remotely-located monitoring and or monitoring and automatic control stations each including an automation controller for local control and automation, and each in communication via a dual-ring communication topology for system or wide-area control. The dual-ring facilitates redundant peer-to-peer data exchange to provide upstream and downstream water flow and water quality information. Systems described herein may calculate flow differential based on water flow data from each of the monitoring stations, and control flow based on the calculated flow differential.

Disclosed is a control system for a water network. The control system includes a plurality of remotely-located monitoring and or monitoring and automatic control stations each including an automation controller for local control and automation, and each in communication via a dual-ring communication topology for system or wide-area control. The dual-ring facilitates redundant peer-to-peer data exchange to provide upstream and downstream water flow and water quality information. Systems described herein may calculate flow differential based on water flow data from each of the monitoring stations, and control flow based on the calculated flow differential.