A dielectric assembly for generating ozone includes a positive electrode, a negative electrode, a dielectric for generating the ozone, and a knob adapted to extend outside of a housing into which the dielectric assembly is to be placed. A system is also provided for sanitizing and deodorizing water, food, surfaces and air including a microbiological reduction filter device having an input connected to a water supply, a venturi injector disposed within a housing and connected to an output of the microbiological reduction filter device which generates ozone and mixes the generated ozone with the water, and an electrode assembly comprising a plurality of electrodes, a dielectric for generating the ozone, and a knob extending outside of the housing. The dielectric in a first embodiment and the entire dielectric assembly in a second embodiment can be removed from the housing and replaced in its entirety by the knob.

An ozone generation apparatus includes a cylindrical shaped first electrode, a cylindrical shaped second electrode disposed coaxially with the first electrode and disposed in the first electrode, a dielectric disposed between the first electrode and the second electrode. Dry air is supplied between the first electrode and the second electrode as raw material gas. A discharge gap length d formed by the first electrode, the second electrode, and the dielectric is set to be in a range of 0.3 to 0.5 mm. A pd product, which is a product of the discharge gap length d and a gas pressure p of the raw material gas, is in a range of 6 to 16 kPa.Math.cm. And the discharge gap length d and the gas pressure p of the raw material gas are set to satisfy following expression.

A water treatment device includes a grounding electrode having a planar flowing water portion that causes treatment target water to flow, a multiple of wire form high voltage electrodes provided parallel with the flowing water portion in a position distanced from the flowing water portion of the grounding electrode and to extend in a direction intersecting a flow direction of the treatment target water, and a blowing device that forms a gas flow that intersects an extension direction of the high voltage electrode and intersects an extension direction of an electrical discharge. This kind of configuration is such that even when water droplets adhere to the high voltage electrode, the water droplets are blown away by a pressure of the gas flow formed by the blowing device, and a spark discharge is restricted.

An ozone generator includes a container, a first metal electrode, a dielectric electrode, a heat pipe, a heat sink, and a power supply unit. The first metal electrode is a cylindrical electrode the axial direction of which is a first direction, and disposed in the container. A cooling medium is supplied to an outer peripheral surface thereof. The dielectric electrode is a cylindrical electrode that is disposed to be opposed to an inner peripheral surface of the first metal electrode, and is coaxial with the first metal electrode. The heat pipe is disposed to be opposed to an inner peripheral surface of the dielectric electrode, and has electrical conductivity. The heat sink is disposed on the outside as an outer space of a space between the first metal electrode and the heat pipe, and connected to the heat pipe.

Method for producing ozone in an ozone generating machine, comprising the steps of: supplying feed gas containing dioxygen at a gas inlet (O2IN) of an ozone generator (OzG), at a given feed gas flow and feed gas pressure, supplying an alternating electric current so as to create electric discharges to generate a given amount of ozone at a gas outlet (O3OUT) of the ozone generator (OzG), adjusting electric current power and at least one of a plurality of process parameters comprising, characterized in that the method comprises, during ozone production, the steps of: monitoring electric power and said at least one parameter of the plurality of process parameters, adjusting the feed gas pressure in response to the adjustment of the electric current power and said at least one process parameter.

A long-life discharge tube for ozone generator is provided, including an air inlet tube, a connecting column, an ozone outlet tube, inner and outer quartz tubes, an outer copper foil, first and second high-voltage connecting components. The outer side of the connecting column fits closely to the inner quartz tube. The outer quartz tube is sleeved on the inner cylindrical component. An air gap is provided between the inner and outer quartz tubes. The outer side of the outer quartz tube fits closely to the copper foil whose length is less than that of the inner and outer quartz tubes. Two connecting components for generating high voltage for arcing are respectively connected to the inner cylindrical component and the outermost copper foil. This structure can prevent the oxidation and corrosion due to the electric spark on the connecting column, greatly improving the overall service life of the discharge tube.

An ozone generator includes a first end plate, a second end plate located opposite the first end plate, a metallic electrode held at both ends by the first and second end plates, a dielectric located inside the metallic electrode with a discharge gap, and including an open end on a first end plate side and a closed end on a second end plate side, a conductive film located on an inner surface of the dielectric, and a high voltage feeding terminal electrically coupled to the conductive film. The conductive film and the high voltage feeding terminal are at least partially in a same position as the first end plate in axial direction of the dielectric. An end of the conductive film and an end of the high voltage feeding terminal on a dielectric opening side extend further toward the opening of the dielectric than the first end plate in the axial direction.

A corona discharge apparatus comprising: (a) an elongate inner electrode, (b) an elongate dielectric sleeve mounted on the inner electrode, (c) an elongate outer electrode mounted on the dielectric sleeve, and (d) an ozone-producing region over which the outer electrode extends, the ozone-producing region having an inlet end and an outlet end, the ozone-producing region defined by three sealing members at the inlet end thereof and three sealing members at the outlet end thereof, the sealing members forming a seal between the inner electrode and the dielectric sleeve.

A sterilization case can be reduced, and it is possible to reliably sterilize not only the surface of a mobile communication device but hidden portions thereof as well. A sterilization case includes a case main body and a cover body. The case main body includes a voltage supplying part and a loading part having an electrode sheet. The voltage supplying part includes a boosting circuit, a direct-current conversion circuit, a switch circuit, and a sterilization meter. The boosting circuit supplies the voltage necessary to generate ozone to the electrode sheet. The direct-current conversion circuit performs conversion to a power source voltage of a smartphone as the mobile communication device and outputs to a male connector. The male connector can be connected to a female connector of the smartphone. The cover body is attached to the case main body so as to be able to open and close.

A mobile system is described that that produces and applies an ozonated liquid to clean and sanitize a variety of articles and surfaces. The mobile system includes an ozonated liquid dispensing unit that forms the ozonated liquid from water and ozone gas.