A method of treating flowback and produced water includes transferring flowback and produced water to a chemical treatment apparatus, mixing treatment chemicals with the flowback and produced water, transferring the mixture of treatment chemicals and flowback and produced water to a weir tank comprising a first end, a second end, an internal chamber, and a plurality of baffles positioned throughout the internal chamber to induce turbulent flow, transferring the mixture of treatment chemicals and flowback and produced water to a first settling tank that provides laminar flow, and transferring the mixture of treatment chemicals and flowback and produced water to a second settling tank that provides laminar flow.

The water treatment system can have a tank having an elongated shape with two opposite ends and two transversally opposite sides; a flocculation chamber at one of the opposite ends of the tank, the flocculation chamber having at least one treated water inlet and a mixer and a separation chamber adjacent to the flocculation chamber inside the tank, the separation chamber having at least one treated water outlet. A flow straightener system can be provided having a transversally-oriented wall forming an overflow baffle and extending upwardly between the flocculation chamber and the separation chamber, the transversally-oriented wall having an upper edge and a plurality of vanes being vertically and longitudinally oriented, parallel to one another and transversally interspaced from one another along the upper edge of the wall, the vanes extending in at least one of the two transversally opposite sides of the tank.

A water treatment system, such as a water softening system, having a water treatment tank with at least one distributor plate mounted inside to support filter media and/or ion exchange resin. The water treatment system is designed to treat hard water with a packed ion-exchange filter media and has a distributor plate design for facilitating the ion-exchange within a water softener resin bed, as well as facilitating the regeneration of the resin bed. The distributor plate presents cavities to the topside for entrapping filter media, and the cavities have narrow slits located at the base for allowing fluid to pass. A method for assembling the water treatment tank and supporting inserted distributor plate is shown. The distributor plate rest on and is supported by a domed-shaped structure that can be placed in the bottom portion of the water treatment vessel.

Mesofluidic separator assemblies are provided that can include at least a pair of supports configured to extend within a pressure differential axis, and at least one level of a plurality of members extending between the pair of supports. Separator assemblies are also provided that can include at least individual members of the plurality defining a plurality of levels extending from a first level configured to have initial contact with the fluid to be separated and a last level configured to have final contact with the fluid to be separated. Assemblies are also provided that can include each member in a set of members being aligned along one axis that is neither parallel nor normal to the pressure differential axis. Assemblies are provided that can include a conduit configured to facilitate the flow of fluid along a pressure differential axis with the conduit defining at least one cross sectional area that is open. Methods for size separating particles within a fluid are provided. The methods can include providing a fluid having solid particles of at least two sizes into a conduit having a plurality of members.

Disclosed is a separation device and a method for separating charged particles from a liquid stream. The separation is effected by establishing an ion concentration gradient across the direction of the liquid stream by the introduction of a gas which when contacted with the liquid, in a reversible reaction, forms a soluble ionic species. A concentration gradient is maintained across the direction of the liquid stream which in turn induces separation of charged particles within the liquid stream due to the effect of diffusiophoresis. The device operates using little or no power, and dispenses with the need for filtration media or separation membranes. The device and method is adaptable to any of a number of separation processes, including biological separation processes, water purification and industrial processes.

The disclosed technology relates to a water filtration and delivery system for a dialysis unit. The water nitration and delivery system including: a laminarizer, the laminizer producing a laminarizer flow; an ultrafiltration unit, the ultrafiltration unit being placed downstream and connected to the laminarizer, the ultrafiltration unit receiving the laminar flow from the laminarizer; and at least one carbon filter, the at least one carbon filter being placed downstream from the ultrafiltration unit, the at least one carbon filter receiving the laminar flow, wherein the laminar flow causes less stress on internal components of the ultrafiltration unit and the at least one carbon filter.

Disinfection apparatus having submersible disinfection devices for disinfecting fluid. The disinfection apparatus includes: a pipe having one or more linear segments; one or more disinfection devices installed on the pipe, each of the one or more disinfection devices generating light for disinfecting fluid in a linear segment of the pipe; and a controller electrically coupled to the one or more disinfection devices and controlling the one or more disinfection devices. Another embodiment of the disinfecting apparatus includes; side and bottom walls and a lid that define an enclosed chamber; an inlet and outlet for communicating fluid to the enclosed chamber; a plurality of disinfection devices disposed on the side wall, each of the plurality of disinfection devices generating light for disinfecting fluid inside the enclosed chamber; and a controller electrically coupled to the plurality of disinfection devices and controlling the plurality of disinfection devices.

A fluid sterilizing device (1) includes barrel portion (5) having a channel where fluid to be sterilized flows; inlet (6a) formed on one end portion side of the barrel portion (5); outlet (7a) formed on the other end portion side of the barrel portion (5); a light source (3) that emits ultraviolet light toward the fluid; and a rectifier (12) mounted inside the channel and having a cylindrical through hole. The rectifier (12) includes inner circumferential region R.sub.in expanding from its center in the diameter direction of the channel, and outer circumferential region R.sub.out expanding outside the inner circumferential region R.sub.in. The ratio (t/d).sub.out of the panel thickness t relative to the diameter d of each through hole in the outer circumferential region R.sub.out is larger than the ratio (t/d).sub.in of the panel thickness t relative to the diameter d of each through hole in the inner circumferential region R.sub.in.

The systems and methods described herein relate to use of a reverse diffusion system for removal of dissolved ions from a fluid, for example, salt ions. Specific embodiments include a system for desalinating salt water to produce potable water. The systems and methods can include pulsing low levels of electricity via electrodes in a scrolling pattern, so as to sweep the ions across a unit.

The invention provides an electrolytic cell and, more precisely, an electrolytic cell for the production of disinfecting liquids and detergents, the cell has a cylindrical tubular construction and wherein the cathode and the anode are arranged coaxially one with respect to the other, and wherein the anode has a conical shape. The invention furthermore also provides the operating method of the aforesaid electrolytic cell for the production of the aforementioned disinfectant and detergent liquids.