Methods, systems and devices for PFAS destruction including adding a sulfite salt to an aqueous solution containing PFAS and then irradiating the aqueous solution with light at 222 nm. The method may include adding a base to the aqueous solution in an amount sufficient to raise a pH of the aqueous solution including PFAS to about 10 or more. It may also include adding a halide salt such as a bromide salt or an iodine salt, and further adding a carbonate. Greater than 90%, or greater than 99%, of the PFAS in the solution may be destroyed by irradiating the aqueous solution in this way.

A surface radiator includes a light-emitting semiconductor component and a housing body. The housing body has a cooling channel forming part of a fluid path from an inlet opening to a return opening. A transparent emission window overlies the light-emitting semiconductor component. The housing body provides an attachment surface spaced apart from the emission window for the light-emitting semiconductor component. The arrangement of the emission window on the housing body is formed in a fluid-tight manner. The housing body, the semiconductor component and the emission window delimit an emission chamber. The fluid path is defined by a first cooling channel, which extends from the inlet opening through the housing body to an orifice opening, the emission chamber, and a second cooling channel, which extends from the discharge opening through the housing body to the return opening. The coolant is an electrically insulating liquid, which is transparent for the incident radiation.

Methods, systems and devices for removing iodide from an aqueous solution including submerging an iodophilic electrode in an aqueous solution containing iodide, applying a current to the electrode, and electrochemically oxidizing the iodide to iodine within the electrode. The electrode may include an iodophilic material and an electrically conductive material. It may also include a binder. The iodophilic material may be a starch, chitosan, carboxycellulose, cationic polymer, or an anion exchange membrane material, for example. After oxidizing the iodide to iodine within the electrode, the electrode may be submerged in a second solution and a current may be applied to reduce the iodine and release it from the electrode in the form of iodide into the second solution.

An apparatus for treating fluid with ultraviolet radiation includes a head portion with an inlet conduit that is configured to convey the fluid away from an inlet along a length direction of the inlet conduit and an outlet conduit that is configured to convey the fluid along a length direction of the outlet conduit. The length direction of the inlet conduit and the length direction of the outlet conduit are collinear. A reactor vessel is coupled to the head portion. An LED light source is configured to emit ultraviolet radiation into the inner vessel, and at least a portion of the LED light source is immersed in fluid flowing toward the outlet conduit so that the fluid cools the LED light source. An adapter unit removably attaches reactor vessel and the head portion.

Methods, systems and devices for PFAS destruction including adding a sulfite salt to an aqueous solution containing PFAS and then irradiating the aqueous solution with light at 222 nm. The method may include adding a base to the aqueous solution in an amount sufficient to raise a pH of the aqueous solution including PFAS to about 10 or more. It may also include adding a halide salt such as a bromide salt or an iodine salt, and further adding a carbonate. Greater than 90%, or greater than 99%, of the PFAS in the solution may be destroyed by irradiating the aqueous solution in this way.

Methods, systems, and devices for PFAS destruction including providing water containing PFAS to a reactor vessel, irradiating the water with UV light under conditions to destroy at least a portion of the PFAS, passing the treated water through a selective membrane to form permeate and membrane reject comprising PFAS, providing the membrane reject back to the reactor vessel, providing additional water containing PFAS to the reactor vessel within the reactor vessel or before being provided to the reactor vessel, and irradiating the membrane reject and the additional water containing PFAS within the reactor vessel with UV light. The steps may be repeated a plurality of times such that PFAS that is not destroyed is recycled through the reactor vessel. Sensitizers may be added and may also be recycled in the membrane reject with the PFAS.

Methods, systems and devices for removing iodide from an aqueous solution including submerging an iodophilic electrode in an aqueous solution containing iodide, applying a current to the electrode, and electrochemically oxidizing the iodide to iodine within the electrode. The electrode may include an iodophilic material and an electrically conductive material. It may also include a binder. The iodophilic material may be a starch, chitosan, carboxycellulose, cationic polymer, or an anion exchange membrane material, for example. After oxidizing the iodide to iodine within the electrode, the electrode may be submerged in a second solution and a current may be applied to reduce the iodine and release it from the electrode in the form of iodide into the second solution.

A bottled water dispenser with a system for treating water in a bottle with UV radiation, containing a water intake finger equipped with a source of UV radiation and configured to open the bottle sealed by a cap by pushing a valve installed in the centre of the cap inside to the bottle or by rupturing this valve, wherein a semiconductor LED is used as the source of UV radiation, the semiconductor LED is installed in a recess made at the end face of the water intake finger, so that when the bottle is opened with the water intake finger, the source is inside the bottle, and the radiation of the source is directed towards the water surface and towards the walls of the bottle, and wherein the semiconductor LED is protected by a quartz glass covering the recess.

A fluid sterilization device includes: a flow path tube through which a fluid flows, the flow path tube having a cylindrical tube shape; and a light source unit configured to irradiate an inside of the flow path tube with ultraviolet light. The flow path tube includes a transparent tube through which the ultraviolet light is transmitted, and aluminum film wound around an outer peripheral surface of the transparent tube. The aluminum film is disposed not to be in close contact with at least a portion of the outer peripheral surface of the transparent tube and to have a first air layer.