An example system is configured to manage the storage of water underground using a sensor-based grid system. The example system includes wells, each of which is between a surface and an underground formation capable of storing water received from the surface. The example system includes pumps, at least of which is associated with each well to force water from the surface, through the well, into the underground formation. The example system includes sensors, at least of which is associated with each well. The sensors are configured to communicate sensor data wirelessly. The example system also includes a computing system configured to receive sensor data from each of the sensors and to control operations of one or more of the pumps based on the sensor data.

An example system is configured to manage the storage of water underground using a sensor-based grid system. The example system includes wells, each of which is between a surface and an underground formation capable of storing water received from the surface. The example system includes pumps, at least of which is associated with each well to force water from the surface, through the well, into the underground formation. The example system includes sensors, at least of which is associated with each well. The sensors are configured to communicate sensor data wirelessly. The example system also includes a computing system configured to receive sensor data from each of the sensors and to control operations of one or more of the pumps based on the sensor data.

A method for constructing silos underground to store water.

In various embodiments, the disclosure relates to a system for locating storm and/or waste water to a subsurface region. The system can be sized to replace, in some instances, retention ponds and to increase developable square footage on a region of land. The system can include a conduit for directing a volume of storm and/or waste water to a subsurface region located at least as deep as the aquifer layer. The system can be sized to handle a volume of water generated during a 100 year storm. In certain embodiments, the subsurface region is located directly below a land structure (e.g., a building structure).

In various embodiments, the disclosure relates to a system for locating storm and/or waste water to a subsurface region. The system can be sized to replace, in some instances, retention ponds and to increase developable square footage on a region of land. The system can include a conduit for directing a volume of storm and/or waste water to a subsurface region located at least as deep as the aquifer layer. The system can be sized to handle a volume of water generated during a 100 year storm. In certain embodiments, the subsurface region is located directly below a land structure (e.g., a building structure).

A distributed integrated water management system includes water source supply lines capable of being placed in fluid communication with a separate water source, water discharge lines capable of being placed in fluid communication with a separate water discharge destination, a water source and destination control manifold to allow selected water source supply lines to be placed in fluid communication with selected water discharge lines, and a storm water collection and distribution system which includes a storm water collection conduit to collect storm water runoff, and a plurality of sumps to receive storm water runoff from the storm water collection conduit. The storm water collection and distribution system further includes a collected storm water discharge line in fluid communication with the sumps, and the collected storm water discharge line can be placed in fluid communication with the plurality of water discharge lines via the water source and destination control manifold.

A distributed integrated water management system includes water source supply lines capable of being placed in fluid communication with a separate water source, water discharge lines capable of being placed in fluid communication with a separate water discharge destination, a water source and destination control manifold to allow selected water source supply lines to be placed in fluid communication with selected water discharge lines, and a storm water collection and distribution system which includes a storm water collection conduit to collect storm water runoff, and a plurality of sumps to receive storm water runoff from the storm water collection conduit. The storm water collection and distribution system further includes a collected storm water discharge line in fluid communication with the sumps, and the collected storm water discharge line can be placed in fluid communication with the plurality of water discharge lines via the water source and destination control manifold.

An engineering system for collecting and utilizing regional rainwater includes a rainwater collection system, a water quality treatment system, and a control and allocation system. The rainwater collection system includes a rainwater collection ditch for a hardened underlying surface, a barrier and a water storage tank. The water quality treatment system includes a filter system. The control and allocation system includes a water quality monitoring device, a water level monitor, a control gate and a water pump. The filter system is connected to the underlying surface through the rainwater collection ditch, and the filter system is connected to the water storage tank. The control gate is disposed between the filter system and the water storage tank. The water quality monitoring device and the water level monitor are disposed within the water storage tank. The water pump is used to drain water from the water storage tank.

An engineering system for collecting and utilizing regional rainwater includes a rainwater collection system, a water quality treatment system, and a control and allocation system. The rainwater collection system includes a rainwater collection ditch for a hardened underlying surface, a barrier and a water storage tank. The water quality treatment system includes a filter system. The control and allocation system includes a water quality monitoring device, a water level monitor, a control gate and a water pump. The filter system is connected to the underlying surface through the rainwater collection ditch, and the filter system is connected to the water storage tank. The control gate is disposed between the filter system and the water storage tank. The water quality monitoring device and the water level monitor are disposed within the water storage tank. The water pump is used to drain water from the water storage tank.

A distributed integrated water management system includes water source supply lines capable of being placed in fluid communication with a separate water source, water discharge lines capable of being placed in fluid communication with a separate water discharge destination, a water source and destination control manifold to allow selected water source supply lines to be placed in fluid communication with selected water discharge lines, and a storm water collection and distribution system which includes a storm water collection conduit to collect storm water runoff, and a plurality of sumps to receive storm water runoff from the storm water collection conduit. The storm water collection and distribution system further includes a collected storm water discharge line in fluid communication with the sumps, and the collected storm water discharge line can be placed in fluid communication with the plurality of water discharge lines via the water source and destination control manifold.