An apparatus for filtering and mineralizing a fluid. The apparatus includes an amount of contaminated fluid located in a reservoir and a cartridge that is located downstream from the reservoir and in fluid communication with it. A filter is in fluid communication with the reservoir and the cartridge. The contaminated fluid is pumped along a pathway from the reservoir to the cartridge so that the contaminated fluid moves through the filter to generate filtered fluid in the cartridge. A pre-determined amount of an additive is associated with the cartridge for adding to the filtered fluid to generate a final fluid with the amount of the additive material.

An apparatus for filtering and mineralizing a fluid. The apparatus includes an amount of contaminated fluid located in a reservoir and a cartridge that is located downstream from the reservoir and in fluid communication with it. A filter is in fluid communication with the reservoir and the cartridge. The contaminated fluid is pumped along a pathway from the reservoir to the cartridge so that the contaminated fluid moves through the filter to generate filtered fluid in the cartridge. A pre-determined amount of an additive is associated with the cartridge for adding to the filtered fluid to generate a final fluid with the amount of the additive material.

A modular element for making reverse osmosis filtering devices includes: at least one first container and a second container, each of which is provided with a tubular lateral wall, with a bottom plate which closes a first axial end of said lateral wall, with an inlet, with a first outlet and with a second outlet, the first and second containers being arranged so that the respective lateral walls are arranged adjacent and have mutually parallel central axes, and a scavenging duct which connects the second outlet of the first container with the inlet of the second container, the first container, the second container and the scavenging duct are obtained as a single monolithic body.

A modular element for making reverse osmosis filtering devices includes: at least one first container and a second container, each of which is provided with a tubular lateral wall, with a bottom plate which closes a first axial end of said lateral wall, with an inlet, with a first outlet and with a second outlet, the first and second containers being arranged so that the respective lateral walls are arranged adjacent and have mutually parallel central axes, and a scavenging duct which connects the second outlet of the first container with the inlet of the second container, the first container, the second container and the scavenging duct are obtained as a single monolithic body.

A container for filtering devices includes: a tubular lateral wall, a bottom plate which closes a first axial end of said lateral wall, and a closing system configured to close—in an openable fashion—a second and opposite axial end of said lateral wall. The closing system includes: an occlusion element, which includes a cylindrical lower portion coaxially insertable into the lateral wall, and an upper portion from which one or more abutment elements configured to rest on the edge of the second axial end of the lateral wall project, one or more coaxial annular seats on the outer lateral surface of the lower portion of the occlusion element configured to receive an annular sealing gasket, and a tightening member including a ring nut configured to surround the occlusion element and to be axially constrained to the lateral wall's exterior, at the second axial end thereof.

A container for filtering devices includes: a tubular lateral wall, a bottom plate which closes a first axial end of said lateral wall, and a closing system configured to close—in an openable fashion—a second and opposite axial end of said lateral wall. The closing system includes: an occlusion element, which includes a cylindrical lower portion coaxially insertable into the lateral wall, and an upper portion from which one or more abutment elements configured to rest on the edge of the second axial end of the lateral wall project, one or more coaxial annular seats on the outer lateral surface of the lower portion of the occlusion element configured to receive an annular sealing gasket, and a tightening member including a ring nut configured to surround the occlusion element and to be axially constrained to the lateral wall's exterior, at the second axial end thereof.

High energy consumption and the negative impacts of hyper saline brine are the two biggest hurdles to a widespread adoption of seawater desalination. Taking advantage of the principal that fluid pressure increases in direct proportion to depth, this invention reduces energy consumption by relocating the process of reverse osmosis at depths where the weight of the water produces the pressure required to drive the reverse osmosis process thereby eliminating the high costs normally associated with raising intake pressure and by simply varying pumping rates, the brine stream can be pre-diluted to levels slightly above the original thereby reducing environmental impact. The simplicity of the design also reduces the costs of building and installation thereby making it likely that seawater desalination will proliferate around the world.

High energy consumption and the negative impacts of hyper saline brine are the two biggest hurdles to a widespread adoption of seawater desalination. Taking advantage of the principal that fluid pressure increases in direct proportion to depth, this invention reduces energy consumption by relocating the process of reverse osmosis at depths where the weight of the water produces the pressure required to drive the reverse osmosis process thereby eliminating the high costs normally associated with raising intake pressure and by simply varying pumping rates, the brine stream can be pre-diluted to levels slightly above the original thereby reducing environmental impact. The simplicity of the design also reduces the costs of building and installation thereby making it likely that seawater desalination will proliferate around the world.

A water recycling apparatus contains: a body, and inflow pipe, a reverse osmosis (RO) discharge pipe, and an outlet pipe. The body includes an accommodation chamber, a first receiving orifice, a second receiving orifice, and a third receiving orifice. The inflow pipe includes a first inlet, a first connection segment, and a first outlet. The RO discharge pipe includes a second inlet, a second connection segment, and a one-way check valve. The one-way check valve has a feeding segment and a discharging segment, such that the RO discharge pipe is connected with the feeding segment of the one-way check valve. The outlet pipe includes a guiding orifice, a third connection segment, and a leading orifice. The body further includes a first layer, a second layer, an inflatable layer, and an air nozzle communicating with the inflatable layer so as to inflate or deflate airs to the inflatable layer.

A water recycling apparatus contains: a body, and inflow pipe, a reverse osmosis (RO) discharge pipe, and an outlet pipe. The body includes an accommodation chamber, a first receiving orifice, a second receiving orifice, and a third receiving orifice. The inflow pipe includes a first inlet, a first connection segment, and a first outlet. The RO discharge pipe includes a second inlet, a second connection segment, and a one-way check valve. The one-way check valve has a feeding segment and a discharging segment, such that the RO discharge pipe is connected with the feeding segment of the one-way check valve. The outlet pipe includes a guiding orifice, a third connection segment, and a leading orifice. The body further includes a first layer, a second layer, an inflatable layer, and an air nozzle communicating with the inflatable layer so as to inflate or deflate airs to the inflatable layer.