The present invention provides a system for solar and/or rainwater harvesting to be installed in open spaces to store the rainwater or charge ground water level and/or to harvest solar energy. The system for rainwater harvesting to be installed in open spaces, comprising at least one canopy to be installed for capturing rainwater in the open space, having inverted cone-like structure to capture water and at least one discharge opening for outflow of the captured water; a storage unit for storing the captured water; a connecting means extending from the discharge opening of the canopy to the storage unit for allowing flow of the captured water from the canopy to the storage unit; and at least two filtration means adapted between the canopy and the storage unit for filtering the captured water.

The present invention provides a system for solar and/or rainwater harvesting to be installed in open spaces to store the rainwater or charge ground water level and/or to harvest solar energy. The system for rainwater harvesting to be installed in open spaces, comprising at least one canopy to be installed for capturing rainwater in the open space, having inverted cone-like structure to capture water and at least one discharge opening for outflow of the captured water; a storage unit for storing the captured water; a connecting means extending from the discharge opening of the canopy to the storage unit for allowing flow of the captured water from the canopy to the storage unit; and at least two filtration means adapted between the canopy and the storage unit for filtering the captured water.

A system of components, which, when assembled, form a rainwater separator for a downpipe is disclosed. The system includes, among other things, a screen for fine filtering of the rainwater. In a first assembly arrangement, the parts are assembled to form a rainwater separator with the screen so that the filtered water can be used as non-potable water for the household. In a second assembly arrangement, the screen is omitted, so that the water obtained from the rainwater separator may be utilized for watering the garden, for example.

A system of components, which, when assembled, form a rainwater separator for a downpipe is disclosed. The system includes, among other things, a screen for fine filtering of the rainwater. In a first assembly arrangement, the parts are assembled to form a rainwater separator with the screen so that the filtered water can be used as non-potable water for the household. In a second assembly arrangement, the screen is omitted, so that the water obtained from the rainwater separator may be utilized for watering the garden, for example.

One or more devices for being received within a downspout of a rain gutter assembly are provided. The one or more devices may be provided for collecting rainwater flowing through the gutter assembly. One or more collection tanks for storing collected rainwater are also provided. One or more accessory devices for use with the one or more collector devices and the one or more storage tanks are also provided.

One or more devices for being received within a downspout of a rain gutter assembly are provided. The one or more devices may be provided for collecting rainwater flowing through the gutter assembly. One or more collection tanks for storing collected rainwater are also provided. One or more accessory devices for use with the one or more collector devices and the one or more storage tanks are also provided.

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.

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 rainwater collection device for collecting rainwater includes a tank that is substantially box-shaped. The tank has a top, a bottom, a tongue end, a groove end and opposing sides. A female coupler is centrally positioned in the groove end and a male coupler, complimentary to the female coupler, is centrally positioned in the tongue end. A top knockout is positioned in the top proximate to the groove end, and a bottom knockout is positioned in the bottom proximate to the groove end. A screen is reversibly couplable to the top knockout. The tank comprises a plurality of tanks. The plurality of tanks is mutually horizontally couplable and mutually vertically couplable, such that the plurality of tanks forms a wall of tanks. Each of the plurality of tanks is fluidically interconnected.

A modular rainwater collection device for collecting rainwater includes a tank that is substantially box-shaped. The tank has a top, a bottom, a tongue end, a groove end and opposing sides. A female coupler is centrally positioned in the groove end and a male coupler, complimentary to the female coupler, is centrally positioned in the tongue end. A top knockout is positioned in the top proximate to the groove end, and a bottom knockout is positioned in the bottom proximate to the groove end. A screen is reversibly couplable to the top knockout. The tank comprises a plurality of tanks. The plurality of tanks is mutually horizontally couplable and mutually vertically couplable, such that the plurality of tanks forms a wall of tanks. Each of the plurality of tanks is fluidically interconnected.