Individual honeycomb shaped modules used in an assembly for underground storage of storm water and other fluid storage needs. Modules are assembled into a resultant honeycomb shape for maximized structural strength and material use efficiency. Internal hexagonal or square shaped modules are assembled and encased by external hexagonal or square shaped modules. Internal adjacent modules are in direct fluid communications with one another through a channel-less chamber. Internal hexagonal or square shaped modules drain into external hexagonal or square shaped modules chamber where fluid is either stored or drained. Assemblies include various top and side pieces along with access ports for entry into said assembly.

A modular solar-energy and rainwater collection apparatus (10) comprising: a collector mount (12) adapted both for securement to a building and to an angularly-adjustable support (110); a plurality of rainwater collectors (14) supportable by the collector mount (12), each rainwater collector (14) having a base (18), and at least one solar-cell retainer (20), for securing at least one solar cell (22) relative to the base (18) of at least one said rainwater collector (14); and connection means (16), for rigidly interconnecting a plurality of like rainwater collectors (14) so that the bases (18) are in abutted liquid communication with each other thus forming a modular rainwater collection area (36).

A modular solar-energy and rainwater collection apparatus (10) comprising: a collector mount (12) adapted both for securement to a building and to an angularly-adjustable support (110); a plurality of rainwater collectors (14) supportable by the collector mount (12), each rainwater collector (14) having a base (18), and at least one solar-cell retainer (20), for securing at least one solar cell (22) relative to the base (18) of at least one said rainwater collector (14); and connection means (16), for rigidly interconnecting a plurality of like rainwater collectors (14) so that the bases (18) are in abutted liquid communication with each other thus forming a modular rainwater collection area (36).

The invention is a system and method for the generation of usable water from atmospheric water vapor for dispersal through water sprinklers.

The invention is a system and method for the generation of usable water from atmospheric water vapor for dispersal through water sprinklers.

The object of the present patent comprises an innovative system for harvesting runoff from rainwater and other sources, basically comprising tube-like vertical deposits with varied and adequate diameters to facilitate both assembly and construction of walls and fences, being self-supporting, modular, cost-effective, either built-in or surface-installed, being formed basically by vertical cylindrical pipes (2), preferably standard PVC water pipes, with the possibility of using metal or polymer sleeves along their lengths or applying an inner lining with fiber glass or any other material aimed at increasing the strength of large diameter pipes.

The object of the present patent comprises an innovative system for harvesting runoff from rainwater and other sources, basically comprising tube-like vertical deposits with varied and adequate diameters to facilitate both assembly and construction of walls and fences, being self-supporting, modular, cost-effective, either built-in or surface-installed, being formed basically by vertical cylindrical pipes (2), preferably standard PVC water pipes, with the possibility of using metal or polymer sleeves along their lengths or applying an inner lining with fiber glass or any other material aimed at increasing the strength of large diameter pipes.

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.

Individual four-sided shaped modules used in an assembly for underground storage of storm water and other fluid storage needs. Modules are assembled into a resultant four-sided tiling shape for maximized structural strength and material use efficiency. Internal four-sided shaped modules are assembled and encased by external four-sided shaped modules. Internal adjacent modules are in direct fluid communications with one another through a channel-less chamber. Internal four-sided shaped modules drain into four-sided shaped modules chamber where fluid is either stored or drained. Assemblies include various top and side pieces along with access ports for entry into said assembly.