A sterilization system includes a controller, a transformer including a primary side in communication with the controller and secondary side, an ozone generator in communication with the secondary side of the transformer and the controller, and a power source in communication with the controller, wherein the ozone generator ionizes atmospheric oxygen through the application of corona discharge.

A dinitrogen pentoxide generating device and a method for generating dinitrogen pentoxide. An NOx generating unit is able to use, as a raw material gas, a gas containing nitrogen and oxygen and produce a plasma to generate a nitrogen oxide. An ozone generating unit is able to use, as a raw material gas, the gas containing nitrogen and oxygen or a gas obtained after the plasma has been produced by the NOx generating unit and produce a plasma to generate ozone. A mixing unit is able to hold the nitrogen oxide generated by the NOx generating unit and the ozone generated by the ozone generating unit in the same space for a predetermined time to generate dinitrogen pentoxide.

A dinitrogen pentoxide generating device and a method for generating dinitrogen pentoxide. An NOx generating unit is able to use, as a raw material gas, a gas containing nitrogen and oxygen and produce a plasma to generate a nitrogen oxide. An ozone generating unit is able to use, as a raw material gas, the gas containing nitrogen and oxygen or a gas obtained after the plasma has been produced by the NOx generating unit and produce a plasma to generate ozone. A mixing unit is able to hold the nitrogen oxide generated by the NOx generating unit and the ozone generated by the ozone generating unit in the same space for a predetermined time to generate dinitrogen pentoxide.

A gas conditioner 60 comprises: a case 62 that forms a gas flowpath 61 through which gas flows; and resin members 80 that are provided to the gas flowpath 61 and that are water permeable. The resin members 80 are formed of sealed hollow bodies that are filled with water.

A gas conditioner 60 comprises: a case 62 that forms a gas flowpath 61 through which gas flows; and resin members 80 that are provided to the gas flowpath 61 and that are water permeable. The resin members 80 are formed of sealed hollow bodies that are filled with water.

A fluid delivery system illustratively includes a spout, at least one valve in fluid communication with the spout, and a disinfectant device, illustratively an antibacterial device, fluidly coupled to the spout. The faucet is configured to selectively flow water through the disinfectant device in response to a user input to the faucet. In another illustrative embodiment, the fluid delivery system includes an outer housing, a plurality of fluid devices supported by the outer housing, and an ozone generator fluidly coupled to the fluid devices.

Embodiments of the invention relate to devices, systems, and methods for selectively emitting scent control material responsive to local conditions of a scent control device. The local conditions may dictate the effectiveness of a given set of output parameters of a scent control device. The scent control device accepts as input, one or more conditional inputs carrying information about the local conditions around the scent control device, such as weather conditions, elevation, barometric pressure, or functional status of the scent control device. Operational programs corresponding to the conditional inputs may be automatically selected based on the combination of conditional inputs to cause the output parameters of the scent control device to match or take into account the local conditions. The scent control device then outputs scent control material such as ozone at a rate effective to control one or more scents to a level that is not perceivable by animals or humans.

An ozone replenishment system including a housing assembly, an electrolysis assembly, a power assembly, and an ozone assembly is disclosed herein. The housing assembly includes a hollow tower. The power assembly includes a battery. The electrolysis assembly includes a reservoir filled with an electrolyte. The electrolysis assembly also includes an anode electrode a cathode electrode disposed into the reservoir. The anode electrode and the cathode electrode are connected to the battery. The electrolysis assembly produces oxygen and dihydrogen. The oxygen is captured by the hollow tower. The ozone assembly includes a fan that allows the oxygen to cross the hollow tower. The ozone assembly further includes a plurality of ultraviolet lights to convert the oxygen into ozone. The ozone is replenishment into the atmosphere.

An ozone replenishment system including a housing assembly, an electrolysis assembly, a power assembly, and an ozone assembly is disclosed herein. The housing assembly includes a hollow tower. The power assembly includes a battery. The electrolysis assembly includes a reservoir filled with an electrolyte. The electrolysis assembly also includes an anode electrode a cathode electrode disposed into the reservoir. The anode electrode and the cathode electrode are connected to the battery. The electrolysis assembly produces oxygen and dihydrogen. The oxygen is captured by the hollow tower. The ozone assembly includes a fan that allows the oxygen to cross the hollow tower. The ozone assembly further includes a plurality of ultraviolet lights to convert the oxygen into ozone. The ozone is replenishment into the atmosphere.

An ozone injector device comprising a housing having a water passageway through the housing, a corona tube disposed within the housing, an ozone inlet fitting coupled to the water passageway, the ozone inlet being in fluid communication with the corona tube via a corona discharge tube, and a clearing piston positioned to move into and out of the water passageway directly opposite the ozone inlet. The clearing piston is biased upwards, towards to the ozone inlet, and configured to prevent flow of ozone into the water passageway.