CORONA UNLOADING REACTION SYSTEM AND PROCEDURE FOR THE EXECUTION OF REACTIONS BY CORONA DISCHARGES

ROEHRENOZONISATOR

ROEHRENOZONISATOR

Ozone generator unit and system

The present disclosure seeks to provide an ozone generator unit. The present disclosure also seeks to provide an ozone generator system. The present disclosure seeks to provide a solution to the existing problems of pressure variations and cooling of ozone generators. An aim of the present disclosure is to provide a solution that overcomes at least partially the problems encountered in prior art, and provides a solution for uniform flow of the gas stream, and efficient cooling for ozone generators. Disclosed is an ozone generator unit. The ozone generator unit comprises a housing (102). The housing comprises a first half (104) having a first recess (204) and a second half (106) having a second recess (206). The ozone generator unit further comprises an inlet (202) and an outlet (110) in the housing, a first dielectric disc (210) arranged within the first recess in contact with an inner surface (240) of the first half, a second dielectric disc (214) arranged within the second recess in contact with an inner surface (242) of the second half, and a high voltage electrode (218), having a gas passage (220), arranged between the first and second dielectric discs. The high voltage electrode is spaced apart from the first and second dielectric discs using a first spacer (230) and a second spacer (232) to constitute a first gas chamber (250) and a second gas chamber (252) on either side of the high voltage electrode.

OZONATED LIQUID DISPENSING UNIT

Abstract A reaction vessel and an ozonated liquid dispensing unit are described herein. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The reaction vessel is incorporated into the unit to reduce bubbles of ozone gas and to break up bubbles of ozone gas in the ozonated liquid to provide a more effective and longer lasting cleaning and sanitizing solution.

MULTIPLE OXYGEN ALLOTROPE GENERATOR

An oxygen allotrope generator (101) having a tube (103) with an electrically grounded outer surface (104) and an electrically positive inner surface (105). A plurality of corona reaction plates (116) are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires (117, 118, 121) and being in electrical connection with the electrically positive (109, 110) inner surface of the tube. An outer jacket (112) encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections (108) at the locations of the corona reaction.

OZONATED LIQUID DISPENSING UNIT

A ozonated liquid dispensing unit is described. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The unit includes a liquid input port to receive liquid into the unit. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with the liquid input port. The injector in supply communication with the second dielectric cell for receiving the ozone gas from the second dielectric cell, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid ...

Corona-Reaktorzelle zum Behandeln fluider Medien mittels einer Coronaentladung und Verfahren zum Betrieb der Zelle

Einrichtung zum Behandeln fluider Medien mittels einer Coronaentladung und Verfahren zum Betrieb dieser Einrichtung

Ozone generator for enriching air with ozone

The ozone generator is used to enrich air with ozone. It has electrodes (8, 12) which are separated from each other by glass (1). The glass is a double-walled glass tube (1), the outer surface and inner surface of which each have at least one electrically conductive part, one part being provided as anode and the other as cathode in order to generate ozone in the cavity (3) between anode (8, 12) and cathode (12, 8). The inner space (15) of the glass tube (1) is partly designed as a vessel for a fluid insulating medium. For this purpose, a sealing part (17), outside the electrode region, which seals off the inner space (15) of the glass tube (1) from the outside is, outside the electrode region, used to form, together with the glass-tube inner wall, a container which is sealed off at least on one side and is intended to receive the insulating material. Air is supplied at the top through the connecting stub (5) and the ozone is discharged at the bottom through the connecting stub (6). Подробнее

Process for the production of ozone and plant for implementation

The air is separated into an oxygen stream and a nitrogen stream. ry oxygen passes successively through a series of discharge ozone generators. After each passage through a generator, the oxygen laden with ozone is cooled in a cooler. After the last cooling, the air laden with ozone passes alternatively through two silica gel beds working alternately in adsorption of ozone and desorption of ozone by means of the nitrogen stream. The oxygen stream, free from its ozone, is recycled to the first generator after passing through a purifier. The efficiency of the adsorption of the ozone by the silica gel is improved by the preliminary cooling of the oxygen laden with ozone.

Ozone generator having double wall glass tube

Ozone generator having double wall glass tube with electrically conducting surfaces to create arc across gap ...

DEVICE FOR THE PRODUCTION OF OZONE.

Flat assembly for generating ozone from air comprises a dielectric support sandwiched between two electrode arrays of different geometry, with only the rear array supplied with voltage

Flat assembly for generating ozone from air comprises a dielectric support sandwiched between two electrode arrays of different geometry coated with insulating material. The rear array comprises at least two flat electrodes supplied with AC voltage and the front array comprises at least two electrically connected electrode structures comprising multiple geometric elements with a maximum possible ratio between edge length and geometric surface area.

DEVICE FOR THE PRODUCTION OF OZONE.

Improvements with the apparatus and process for the production of ozone

APPARATUS FOR HIGHLY EFFICIENT COLD-PLASMA OZONE PRODUCTION

An apparatus comprising a cold-plasma ozone generator, the ozone generator comprising: a non-arcing non-coronal ozone production cell capable of generating ozone; the ozone production cell having a pair of electrodes placed on two sides of the production cell and spaced apart by an electrode gap, and a dielectric layer on each of the electrodes facing inward into the ozone production cell; a high-voltage pulse generator attached to the electrodes and configured for producing a glow discharge cold plasma between the electrodes, the high-voltage pulse generator being able to produce sufficient voltage to generate the glow discharge cold plasma; a cooling system attached to each of the electrodes; and an oxygen source adapted to provide gas flow through the production cell in the gap between the pair of electrodes that efficiently generates ozone in the cold plasma, wherein the dielectric layers are intimately and directly bonded to each of the electrodes.

KORONAENTLADUNGS-REAKTIONSSYSTEM UND VERFAHREN ZUR DURCHFUEHRUNG VON REAKTIONEN DURCH KORONAENTLADUNGEN

MODULAR OZONE MANUFACTURE SYSTEM

OZONE GENERATOR APPARATUS AND METHOD

Ozonated liquid dispensing unit

A reaction vessel and an ozonated liquid dispensing unit are described herein. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The reaction vessel is incorporated into the unit to reduce bubbles of ozone gas and to break up bubbles of ozone gas in the ozonated liquid to provide a more effective and longer lasting cleaning and sanitizing solution.

OZONATED LIQUID DISPENSING UNIT

A reaction vessel and an ozonated liquid dispensing unit are described herein. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The reaction vessel is incorporated into the unit to reduce bubbles of ozone gas and to break up bubbles of ozone gas in the ozonated liquid to provide a more effective and longer lasting cleaning and sanitizing solution.

OZONIZED STI LIQUID DISTRIBUTION DEVICE

Описано устройство раздачи озонированной жидкости. Устройство вырабатывает и раздает озонированную жидкость, которую можно использовать для очистки и дезинфекции различных изделий или использовать совместно с процессами очистки и другим оборудованием. Устройство включает в себя отверстие подвода жидкости для подачи жидкости в устройство. Устройство включает в себя первую диэлектрическую камеру для выработки газообразного озона из окружающего воздуха и вторую диэлектрическую камеру для выработки газообразного озона. Первая диэлектрическая камера находится в соединении питания со второй диэлектрической камерой для подачи во вторую диэлектрическую камеру сырьевого газа, содержащего газообразный озон, генерируемый из окружающего воздуха. Вторая диэлектрическая камера вырабатывает из сырьевого газа газообразный озон. Инжектор находится в жидкостной связи с отверстием подвода жидкости. Инжектор находится в соединении питания со второй диэлектрической камерой для приема газообразного озона из второй диэлектрической камеры, и инжектор смешивает газообразный озон из второй диэлектрической камеры с жидкостью из отверстия подвода жидкости для выработки озонированной жидкости. Отверстие отвода жидкости выводит озонированную жидкость из устройства. Для управления выпуском озонированной жидкости из устройства можно использовать кран или распылитель. A device for dispensing ozonized liquid is described. The device produces and dispenses ozonized liquid that can be used to clean and disinfect various products or be used in conjunction with cleaning processes and other equipment. The device includes a liquid inlet port for supplying liquid to the device. The device includes a first dielectric chamber for generating ozone gas from ambient air and a second dielectric chamber for generating ozone gas. The first dielectric chamber is in power connection with the second dielectric chamber to supply to the second dielectric chamber a feed gas containing ozone gas generated from ambient ...

Ozone generator having double wall glass tube - with electrically conducting surfaces to create arc across gap

O3 generator to enrich air with O3 consists of a pair of electrodes separated by glass. This is in the form of a double walled glass tube forming an annular passage between. Part of the surfaces are made conducting to form electrodes and then a high voltage between the anode and cathode is applied. This creates an electric arc in the passage through which an air stream is passed. By this means O3 is formed in the air. The inner surface is created the anode and the outer surface the cathode. The electrically conducting portion is formed from metal foil and/or a metallised deposit such as a metallised plastic paint coating. Air is fed in at one end and the O3 enriched air comes out at the other. For use with water preparation e.g. for drinking or swimming baths.

PROCESS AND APPARATUS OF CONTINUOUS OZONE CREATION AND RECOVERY

Dispositif pour la production d'ozone.

Dispositif pour la production d'ozone à partir d'oxygène par décharges électriques silencieuses dans une fente de décharge (9) essentiellement formée par une électrode extérieure (4) tubulaire et par des électrodes intérieures (7) tubulaires entourées concentriquement par l'électrode extérieure et pourvues d'un diélectrique (18), lesquelles électrodes sont reliées galvaniquement entre elles, ainsi que par des moyens (8) d'écartement du diélectrique (18) par rapport à l'électrode extérieure (4). Les tubes intérieurs (7) sont pourvus frontalement de surfaces de contact (10) et sont maintenus ensemble au moins par groupes, par des moyens de serrage (11).

DEVICE FOR the PRODUCTION Of OZONE.

Dispositif pour la production d'ozone à partir d'oxygène par décharges électriques silencieuses dans une fente de décharge (9) essentiellement formée par une électrode extérieure (4) tubulaire et par des électrodes intérieures (7) tubulaires entourées concentriquement par l'électrode extérieure et pourvues d'un diélectrique (18), lesquelles électrodes sont reliées galvaniquement entre elles, ainsi que par des moyens (8) d'écartement du diélectrique (18) par rapport à l'électrode extérieure (4). Les tubes intérieurs (7) sont pourvus frontalement de surfaces de contact (10) et sont maintenus ensemble au moins par groupes, par des moyens de serrage (11). Device for the production of ozone from oxygen by silent electric discharges in a discharge slot (9) essentially formed by an outer tubular electrode (4) and by inner tubular electrodes (7) surrounded concentrically by the outer electrode and provided with a dielectric (18), which electrodes are galvanically connected to each other, as well as by means (8) for spacing the dielectric (18) with respect to the outer electrode (4). The inner tubes (7) are provided frontally with contact surfaces (10) and are held together at least in groups, by clamping means (11).

ROEHRENOZONISATOR

CORONA UNLOADING REACTION SYSTEM AND PROCEDURE FOR THE EXECUTION OF REACTIONS BY CORONA DISCHARGES

OZONE GENERATOR UNIT AND SYSTEM

The present disclosure seeks to provide an ozone generator unit. The present disclosure also seeks to provide an ozone generator system. The present disclosure seeks to provide a solution to the existing problems of pressure variations and cooling of ozone generators. An aim of the present disclosure is to provide a solution that overcomes at least partially the problems encountered in prior art, and provides a solution for uniform flow of the gas stream, and efficient cooling for ozone generators. Disclosed is an ozone generator unit. The ozone generator unit comprises a housing (102). The housing comprises a first half (104) having a first recess (204) and a second half (106) having a second recess (206). The ozone generator unit further comprises an inlet (202) and an outlet (110) in the housing, a first dielectric disc (210) arranged within the first recess in contact with an inner surface (240) of the first half, a second dielectric disc (214) arranged within the second recess in contact with an inner surface (242) of the second half, and a high voltage electrode (218), having a gas passage (220), arranged between the first and second dielectric discs. The high voltage electrode is spaced apart from the first and second dielectric discs using a first spacer (230) and a second spacer (232) to constitute a first gas chamber (250) and a second gas chamber (252) on either side of the high voltage electrode.

Apparatus ozonor

Process for breaking chemical bonds

A process and reactor for chemical conversion is taught. The process allows the selective breaking of chemical bonds in a molecule by use of fast rise alternating current or fast rise pulsed direct current, each fast rise portion being selected to have a suitable voltage and frequency to break a selected chemical bond in a molecule. The reactor for carrying out such a process includes a chamber for containing the molecule and a generator for generating and applying the selected fast rise current.

ГЕНЕРАТОР ОЗОНА И СИСТЕМА ГЕНЕРАТОРОВ ОЗОНА

FIELD: electrical equipment. SUBSTANCE: present invention is aimed at creation of an ozone generator, as well as an ozone generator system. Ozone generator comprises housing (102). Housing comprises first half (104) having first compartment (204) and second half (106) having second compartment (206). In housing there is inlet (202) and outlet (110). First dielectric disc (210) is installed within the first compartment in contact with inner surface (240) of first half (104) of the case. Second dielectric disc (214) is installed within the second compartment in contact with inner surface (242) of the second half. In the main chamber between the first and second dielectric discs high-voltage electrode (218) with gas passage (220) is installed. High-voltage electrode is located at the distance from the first and second dielectric discs using first separating spacer (230) and second separating spacer (232) and to form first gas chamber (25) and second gas chamber (252) on both sides of high-voltage electrode. Gas passage of the high-voltage electrode and the gas passage of the first dielectric disc are made with provision of communication between the first and the second gas chambers. EFFECT: efficient cooling of ozone generator. 16 cl, 3 dwg

Patent RU2019105790A3

ГЕНЕРАТОР ОЗОНА И СИСТЕМА ГЕНЕРАТОРОВ ОЗОНА

Improvements in Method and Apparatus for Producing a Gaseous Reaction by a Silent Discharge.

27,951. British Thomson-Houston Co., [General Electric Co.]. Dec. 12. Gases and vapours, treating electrically. - Chemical reactions in gases such as the production of ozone are effected by submitting the gas to a series of silent electric discharges and mixing the gas after each treatment with more of the gas in an unchanged condition. In one form of construction, the apparatus consists of a dielectric 20 on which is mounted, for example by electrodeposition, an outer electrode 21. The inner electrode is divided into short cylindrical lengths 22 mounted on a central rod 18, and supported on it by arms 25, which are bent so as to deflect the untreated gas passing through the middle of the tube towards the sides, where it mixes with the treated gas. In another form, the inner electrode is continuous and provided with series of holes 41, 42, Fig. 9, which, in conjunction with fan blades 43, allow gas to be diverted from the central space into the discharge gap between the electrode and the dielectric. In yet another form, tongues 44, Fig. 11, are stamped up out of the inner electrode, and these are bent inwards to a gradually increasing extent in the direction of motion of the gas so as gradually to divert the untreated gas into the discharge gap. The elements above described are mounted in a grooved plate 6, Fig. 2, spacing-plates 29 being placea between the end pieces 16, Figs. 2 and 3, if necessary. Air is forced through the apparatus by a blower 12 driven by a motor 13, and passes through the ozonizing-elements mounted in the partition, and through apertures which may have been provided in the spacing-plates 29.

MODULAR OZONE GENERATOR SYSTEM

An ozone generator system (1) in which a multitude of plate type ozone generators (2) are arranged adjacent to each other in a block (3). Each ozone generator comprises a chamber, adapted for converting oxygen to ozone by a corona discharge, and each chamber is provided with an inlet for oxygen or an oxygen-rich gas and an outlet for ozone. Said ozone generators are arranged in a block module (26) in which they are affixed by a block rack (4). Said block rack comprises an inlet port (5) adapted for introduction of oxygen gas, and an outlet port (6) adapted for discharge of ozone created through conversion within the generators comprised in the block module. A multitude of first conduits (7), each running between said inlet port and one chamber inlet, and a multitude of second conduits (8), each running between said outlet port and one chamber outlet, are provided within said block rack. Said conduits are arranged so that the flow distance between the inlet and outlet ports has the same length, regardless of which generator the introduced gas passes through, thereby achieving an even gas pressure and gas flow, through parallel connection of the generators.

PROCESS AND APPARATUS OF CONTINUOUS OZONE CREATION AND RECOVERY

CORONA REACTOR APPARATUS

PROCESS AND APPARATUS FOR CHEMICAL CONVERSION

A process and reactor for chemical conversion is taught. The process allows the selective breaking of chemical bonds in a molecule by use of fast rise alternating current or fast rise pulsed direct current, each fast rise portion being selected to have a suitable voltage and frequency to break a selected chemical bond in a molecule. The reactor for carrying out such a process includes a chamber for containing the molecule and a generator for generating and applying the selected fast rise current.

Multiple oxygen allotrope generator

An oxygen allotrope generator having a tube with an electrically grounded outer surface and an electrically positive inner surface. A plurality of corona reaction plates are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires and being in electrical connection with the electrically positive inner surface of the tube. An outer jacket encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections at the locations of the corona reaction.

HIGH-CAPACITY AND HIGH-PERFORMANCE OZONIZER

PURPOSE: To provide a small-sized highly efficient ozonizer capable of generating a large amount of ozone at a high concentration and a low cost. CONSTITUTION: Plural ozonizing units (5a), etc., are successively connected in series and output voltages from respective AC high-voltage power sources (7a) to (7c) connected to the respective units (5a), etc., are successively and gradually reduced in relation to the flow of a raw material gas 20. Thereby, since ozone generated in the ozonizing units in the former stage is not thermally decomposed in the ozonizing units in the latter stage, a large amount of the ozone can be obtained at a high concentration. COPYRIGHT: (C)1994,JPO&Japio ...

Ozone generating m eans and applications

CELLS FOR CORONA REACTORS

... 1310364 Ozonizers PURIFICATION SCIENCES Inc 22 May 1970 [4 June 1969] 24942/70 Heading H5H A corona reactor 10, such as an ozone generator, comprises a plurality of adjacent, individual airtight corona reactor cells 21, each of which includes a pair of flat, parallel electrodes 152, 154, defining a sealed corona discharge chamber 160 therebetween, both of the electrode interior surfaces 157, 159 being covered with a dielectric layer 156, 158, and both of the electrode exterior surfaces 153, 155, being fluid cooled. Preferred details of the coatings forming the layers 156, 158, are in Specification 1,265,724. Corrugated aluminium heat sink spacers 178, 180, in contact with the electrode exterior surfaces 153, 155, provide a plurality of closed and open channels 186, 188, for cooling air blown through the electrode assembly 14 by a blower 18. The spaces 17, 180 provide electrical connection between adjacent electrodes and also act to uniformly distribute the forces of the pressure-plate 126 ...

CORONA REACTOR METHOD AND APPARATUS

CORONA REACTION SYSTEM

Modular ozone generation system

Ozongenerator

Modular ozone generator system

OZONE GENERATOR

AIR PURIFYING SYSTEM

... 2083967 9118662 PCTABS00008 A closed container (1) has openings (4) at an input end (3) for drawing air into the container and openings (6) at the output end (5) for passing air out of the container. An ozone generator (9) is disposed inside the container adjacent the input end and a corona generator (11) is disposed in the container adjacent the output end. The corona generator includes a dielectric made of a material having a dielectric constant of 1000 or greater. Impure air which is drawn in at the input end passes over the ozone generator whereby the ozone reacts with the impurities of the impure air to provide purified air. The purified air with remaining ozone is passed over the corona generator means to destroy the remaining ozone.

OZONE SYSTEM FOR MULTI-CHAMBER TOOLS

OZONE GENERATION AND RECOVERY SYSTEM

CORONA INDUCED REACTIONS IN GASES

Process and apparatus for chemical conversion

OZONATED LIQUID DISPENSING UNIT

A ozonated liquid dispensing unit is described. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The unit includes a liquid input port to receive liquid into the unit. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with the liquid input port. The injector in supply communication with the second dielectric cell for receiving the ozone gas from the second dielectric cell, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid ...

OZONATED LIQUID DISPENSING UNIT

A reaction vessel and an ozonated liquid dispensing unit are described herein. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The reaction vessel is incorporated into the unit to reduce bubbles of ozone gas and to break up bubbles of ozone gas in the ozonated liquid to provide a more effective and longer lasting cleaning and sanitizing solution.

MODULAR OZONE GENERATOR SYSTEM

An ozone generator system (1) in which a multitude of plate type ozone generators (2) are arranged adjacent to each other in a block (3). Each ozone generator comprises a chamber, adapted for converting oxygen to ozone by a corona discharge, and each chamber is provided with an inlet for oxygen or an oxygen-rich gas and an outlet for ozone. Said ozone generators are arranged in a block module (26) in which they are affixed by a block rack (4). Said block rack comprises an inlet port (5) adapted for introduction of oxygen gas, and an outlet port (6) adapted for discharge of ozone created through conversion within the generators comprised in the block module. A multitude of first conduits (7), each running between said inlet port and one chamber inlet, and a multitude of second conduits (8), each running between said outlet port and one chamber outlet, are provided within said block rack. Said conduits are arranged so that the flow distance between the inlet and outlet ports has the same ...

OZONE GENERATOR

OZONE GENERATOR A concentric-tube type ozone generator wherein the lower end portion of the interior of the tube container a supply of oil which contacts the inner side of the inner tube wall above the ner electrode to prevent the flow of creep currents between the inner and outer electrodes. A second supply of oil can be confined in the upper end portion of the inner tube wall above the inner electrode. The inner electrode may consist of a metallic foil which is biased against the inner side of the inner tube wall by a helical spring. The outer electrode may constitute a helically convoluted metallic wire. Two or more tubes can be mounted above each other with the outlet at the lower end of the upper tube in communication with the inlet at the upper end of the lower tube.

Corona reaction system

OZONE GENERATOR UNIT AND SYSTEM

Disclosed is an ozone generator unit. The ozone generator unit comprises a housing. The housing comprises a first half having a cylindrical first recess and a second half having a cylindrical second recess. The ozone generator unit further comprises an inlet and an outlet in the housing, a first dielectric disc arranged within the first recess in contact with an inner surface of the first half, a second dielectric disc arranged within the second recess in contact with an inner surface of the second half, and a high voltage electrode, having a gas passage, arranged between the first and second dielectric discs. The high voltage electrode is spaced apart from the first and second dielectric discs using a first spacer and a second spacer to constitute a first gas chamber and a second gas chamber on either side of the high voltage electrode.

MODULAR OZONE GENERATOR SYSTEM

An ozone generator system (1) in which a multitude of plate type ozone generators (2) are arranged adjacent to each other in a block (3). Each ozone generator comprises a chamber, adapted for converting oxygen to ozone by a corona discharge, and each chamber is provided with an inlet for oxygen or an oxygen-rich gas and an outlet for ozone. Said ozone generators are arranged in a block module (26) in which they are affixed by a block rack (4). Said block rack comprises an inlet port (5) adapted for introduction of oxygen gas, and an outlet port (6) adapted for discharge of ozone created through conversion within the generators comprised in the block module. A multitude of first conduits (7), each running between said inlet port and one chamber inlet, and a multitude of second conduits (8), each running between said outlet port and one chamber outlet, are provided within said block rack. Said conduits are arranged so that the flow distance between the inlet and outlet ports has the same ...

PRODUCTION OF OZONE

... 1536345 Ozone production UNION CARBIDE CORP 12 March 1976 [12 March 1975 (2)] 09927/76 Heading H5H In an ozone generating system or process, air is separated into oxygen-rich and nitrogen-rich fractions, the oxygen is ozonized, ozone is adsorbed from the ozonized oxygen, the deozonized, oxygen-rich, gas is fed back to the ozonizer, and the ozone is desorbed into the nitrogen-rich gas for use. Air is separated into oxygen- and nitrogen-rich fractions by a molecular sieve or cryogenic means. Preferably two beds of adsorbent are used, alternately being charged with ozone and being desorbed to give a continuous process. The best absorbent is silica gel, particle size > 100 Á. Other absorbents are mentioned. Figures are given illustrating typical operating conditions.

CORONA REACTOR METHOD AND APPARATUS

PROCESS AND APPARATUS FOR OZONE GENERATION

OZONE GENERATOR APPARATUS AND METHOD

A tubular type ozone generator with inner and outer concentric electrodes and a middle dielectric member. One end is sealed to permit feed gas traversing the inner gap between the inner electrode and the dielectric member to reverse direction and to traverse the outer gap between the dielectric member and the outer electrode. A method for producing ozone using a tubular type ozone generator where first the total feed gas is passed in one direction between an electrode and the dielectric member for producing ozone, reversed, and then passed in the reverse direction between the dielectric member and the other electrode producing additional ozone. A hollow inner electrode permits more efficient cooling of the inner electrode. A plurality of ozone generators are combined with intake and output manifolds for the feed gas and produced ozone.

APPARATUS FOR GENERATING OZONE AND/OR O1 USING A HIGH ENERGY PLASMA DISCHARGE

An electro chemical conversion cell that can break down certain gasses to provide ozone and monovalent oxygen from a supplied volume of a suitable 02-containing gas. The conversion cell is provided with at least one metal mesh electrode within a generator reaction chamber, and a power supply which is adapted to supply a high alternating electric current voltage to at least partially break-down O2 in the input gas to yield ozone. A fluid flow passage extends through the reaction chamber as a generally elongated passage through the reaction cavity. The fluid flow passage extends from an upstream end, where the O2-containing gas is initially supplied into the housing, to a downstream end where treated gas either flows outwardly therefrom under pressure or is evacuated from the housing. In a simplified construction, the fluid flow passage is delineated by a series of electrically insulating plates and/or spacers which are used to partition the reaction cavity.

MULTIPLE OXYGEN ALLOTROPE GENERATOR

An oxygen allotrope generator having a tube with an electrically grounded outer surface and an electrically positive inner surface. A plurality of corona reaction plates are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires and being in electrical connection with the electrically positive inner surface of the tube. An outer jacket encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections at the locations of the corona reaction. 1. An oxygen allotrope generator comprising:a tube having a wall of a predetermined thickness, said tube wall having an inner surface and an outer surface and having a first end and a second end;an inlet connected to said first end of said tube and adapted to be coupled to a source of oxygen-containing gas;a first electrically conductive element on the outer surface of said tube, said first element being adapted to be connected to ground;a second electrically conductive element on the inner surface of said tube;a conductor for connecting said second electrically conductive element to a source of electrical power;a tubular jacket surrounding said tube and being spaced from said tube wall by a predetermined distance;an outlet for oxygen allotrope-containing gas to exit from said jacket; anda plurality of spaced corona reaction plates across the interior of said tube, said corona reaction plates being electrically conductive and being electrically connected to said second electrically conductive element.2. The oxygen allotrope generator claim 1 , and further comprising a longitudinal central support wire interconnecting said corona reaction plates.3. The oxygen allotrope generator of claim 1 , and further comprising a plurality of corona reaction wires interconnecting said corona reaction plates.4. The oxygen allotrope generator of claim 1 , and further comprising a plurality of ...

ELEKTRODE FUER EINEN KORONAREAKTOR

CORONA REACTION SYSTEM

Ozone generator having double wall glass tube - with electrically conducting surfaces to create arc across gap

OZONATED LIQUID DISPENSING UNIT

A ozonated liquid dispensing unit is described. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with a liquid input port. The injector is in supply communication with the second dielectric cell for receiving the ozone gas, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid input port to produce an ozonated liquid. A liquid output port discharges the ozonated liquid from the unit.

KORONAREAKTORKERN

VERFAHREN UND VORRICHTUNG ZUM ERZEUGEN UND RUECKGEWINNEN VON OZON

MODULARES OZON HERSTELLUNGSSYSTEM

Ozonated liquid dispensing unit

A ozonated liquid dispensing unit is described. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The unit includes a liquid input port to receive liquid into the unit. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with the liquid input port. The injector in supply communication with the second dielectric cell for receiving the ozone gas from the second dielectric cell, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid ...

APPARATUS FOR GENERATING OZONE AND/OR O1 USING A HIGH ENERGY PLASMA DISCHARGE

An electro chemical conversion cell that can break down certain gasses to provide ozone and monovalent oxygen from a supplied volume of a suitable O2-containing gas. The conversion cell is provided with at least one metal mesh electrode within a generator reaction chamber, and a power supply which is adapted to supply a high alternating electric current voltage to at least partially break-down O2 in the input gas to yield ozone. A fluid flow passage extends through the reaction chamber as a generally elongated passage through the reaction cavity. The fluid flow passage extends from an upstream end, where the O2-containing gas is initially supplied into the housing, to a downstream end where treated gas either flows outwardly therefrom under pressure or is evacuated from the housing. In a simplified construction, the fluid flow passage is delineated by a series of electrically insulating plates and/or spacers which are used to partition the reaction cavity.

APPARATUS FOR GENERATING OZONE AND/OR O1 USING A HIGH ENERGY PLASMA DISCHARGE

An electro chemical conversion cell that can break down certain gasses to provide ozone and monovalent oxygen from a supplied volume of a suitable O2-containing gas. The conversion cell is provided with at least one metal mesh electrode within a generator reaction chamber, and a power supply which is adapted to supply a high alternating electric current voltage to at least partially break-down O2 in the input gas to yield ozone. A fluid flow passage extends through the reaction chamber as a generally elongated passage through the reaction cavity. The fluid flow passage extends from an upstream end, where the O2-containing gas is initially supplied into the housing, to a downstream end where treated gas either flows outwardly therefrom under pressure or is evacuated from the housing. In a simplified construction, the fluid flow passage is delineated by a series of electrically insulating plates and/or spacers which are used to partition the reaction cavity.

Corona reaction system

Sistema gerador de ozÈnio, e, disposição de geradores de ozÈnio

VORRICHTUNG ZUR ERZEUGUNG VON OZON

AIR PURIFYING SYSTEM

OZONE GENERATOR

An ozone generator (1) is presented comprising a body (2), a first electrode (4), a second electrode (6), an elongate channel within the body extending between the first and second electrodes, an inlet (10) and an outlet (12); the elongate channel being in fluid communication with the inlet and the outlet; the elongate channel isolated from each of the first and second electrodes by a respective dielectric layer (22, 24), whereby an electric field can be generated across the elongate channel between the first and second electrodes. The presented ozone generator allows small quantities of ozone to be produced for use in small scale water treatment. In addition, a method of producing ozone is presented using an ozone generator according to the invention.

Corona reaction system

A corona reaction system of the type wherein substantially all of the heat generated by corona discharge is removed from the system by gas flow therethrough. A corona discharge gas flow path is provided which is between 2.0 and 10 inches in length and bounded by discharge electrodes spaced apart at a distance of between 0.01 and 0.250 inch, whereby low pressure drop over the gas flow path is maintained under conditions of high power density and gas temperature.

Improvements in or relating to the Manufacture of Ozone.

... 19,146. Steynis, J. Aug. 21. Gases and vapours, treating electrically. - An ozonizing-apparatus comprises a number of open - ended electrode tubes arranged in series, in combination with a corresponding number of cooling - tubes arranged in series, the cooling-medium Howing in the opposite direction to the air. Each of the electrode tubes 10 ... 15 comprises an inner electrode 19 carrying rings 20, and an insulating tube 18 extending below the electrode surfaces and slidable in its outer electrode 10 &c. so that it can be removed by lifting it through a window 26 The electrode tubes extend between upper and lower chambers 5, 1 divided into compartments 6-9 and 2-4 respectively, which connect the tubes in series, the air entering at 16 and leaving at 17. High-tension current enters at 21 through an insulation 22 at the top of a pipe which encloses a body of stagnant air which prevents the deposition of moisture on the outside around the lead 21 as it does not share in the cooling of the ...

Ozonizing apparatus

... 677,998. Treating gases with discharges. SOC. D'EPURATION ET D'ENTREPRISES, SOC. ANON. March 30, 1949 [April 16, 1948], No. 8674/49. Drawings to Specification. Class 39 (i). [Also in Group XXXV] Two ozonizing condensers of equal capacity are fed by a transformer in Scott connection from a three-phase supply. Each condenser is as described in Specification 677,897.

Ceramic chip ozone generator

The invention relates to the technical field of ozone manufacturing accessory devices, in particular to a ceramic chip ozone generator capable of conveniently cleaning scale on the inner wall of a cooling cylinder. The ceramic chip ozone generator comprises a box body, four groups of supporting legs, a cooling cylinder, a first ceramic chip and a second ceramic chip, a working cavity is formed inthe box body, a box opening is formed in the left end of the box body, a box cover is detachably arranged at the box opening, a water inlet pipe and a water outlet pipe are respectively communicated with the central areas of the left side wall and right side wall of the cooling cylinder, the upper half area and the lower half area of the left side wall of the box cover are communicated with a first air outlet pipe and a second air outlet pipe respectively, the upper half area and the lower half area of the right side wall of the box body are communicated with a first air inlet pipe and a second ...

APPARATUS FOR ENRICHING AN OXYGEN-CONTAINING GAS WITH OZONE

Ozone generator

An ozone generator in which an air pump discharges air through a plurality of juxtaposed, successive, tubular housings, each of which has concentric wire mesh electrodes separated by dielectric tubes. A high a.c. potential, insufficient to cause a spark discharge, is imposed across the electrodes so that the oxygen of the air is progressively converted into ozone. The ozone laden air is directed through non-return valves into water flowing in a pipe for the purpose of destroying bacteria therein.

Apparatus for carrying out plasma discharges in gases

In an ozone generator, the process gas alternately flows through discharge sections (17) in which pulse-induced plasma discharges are carried out and through discharge-free cooling sections (18) in which no discharge takes place. The electrodes (12) have pulses applied to them in such a way that each quantity of gas passing through the discharge section (17) in question is subjected to a discharge process. The cooling between the individual discharge processes results in reduced decay of the ozone formed. In the cooling sections (18), detrimental ions are removed from the process gas. ...

Ozone generator unit and system

The present disclosure seeks to provide an ozone generator unit. The present disclosure also seeks to provide an ozone generator system. The present disclosure seeks to provide a solution to the existing problems of pressure variations and cooling of ozone generators. An aim of the present disclosure is to provide a solution that overcomes at least partially the problems encountered in prior art, and provides a solution for uniform flow of the gas stream, and efficient cooling for ozone generators. Disclosed is an ozone generator unit. The ozone generator unit comprises a housing (102). The housing comprises a first half (104) having a first recess (204) and a second half (106) having a second recess (206). The ozone generator unit further comprises an inlet (202) and an outlet (110) in the housing, a first dielectric disc (210) arranged within the first recess in contact with an inner surface (240) of the first half, a second dielectric disc (214) arranged within the second recess in contact ...

Air purifying system

A closed container (1) has openings (4) at an input end (3) for drawing air into the container and openings (6) at the output end (5) for passing air out of the container. An ozone generator (9) is disposed inside the container adjacent the input end and a corona generator (11) is disposed in the container adjacent the output end. The corona generator includes a dielectric made of a material having a dielectric constant of 1000 or greater. Impure air which is drawn in at the input end passes over the ozone generator whereby the ozone reacts with the impurities of the impure air to provide purified air. The purified air with remaining ozone is passed over the corona generator means to destroy the remaining ozone.

Ozone generator

A concentric-tube type ozone generator wherein the lower end portion of the interior of the tube contains a supply of oil which contacts the inner side of the inner tube wall above the inner electrode to prevent the flow of creep currents between the inner and outer electrodes. A second supply of oil can be confined in the upper end portion of the inner tube wall above the inner electrode. The inner electrode may consist of a metallic foil which is biased against the inner side of the inner tube wall by a helical spring. The outer electrode may constitute a helically convoluted metallic wire. Two or more tubes can be mounted above each other with the outlet at the lower end of the upper tube in communication with the inlet at the upper end of the lower tube.

MODULAR OZONE GENERATOR SYSTEM

Ozone generator consists of series modules arranged in series or parallel

PROJECT I CONTINUE FOR GENERATION AND RECOVERY OF OZONE; PROCESS FOR OZONE GENERATION; E PERFECTIONING IN PROCESS FOR OZONE GENERATION IN MULTIPLE PERIODS OF TRAINING

OZONE SYSTEM FOR MULTI-CHAMBER TOOLS

An improved system and method for controlling ozone concentration in connection with a multi-chamber tool. The system and method involve a first and a second concentration controller in combination with an ozone generator. The first concentration controller detects an EVENT (i.e., one of the chambers in the multi-chamber tool coming on-line or off-line) and in response provides a power instruction to the ozone generator in accordance with a predictive control algorithm. The first concentration controller has a fast (i.e., about 1 second) response time. The second concentration controller is masked from the ozone generator during the EVENT, but otherwise controls the generator after an interval of time has lapsed after the EVENT. The second concentration controller has a slower response time than the first concentration controller, however the second concentration controller provides the system with long-term stability and can be used to provide updated data to the predictive control algorithm ...

Apparatus for chemical conversion

A process and reactor for chemical conversion is taught. The process allows the selective breaking of chemical bonds in a molecule by use of fast rise alternating current or fast rise pulsed direct current, each fast rise portion being selected to have a suitable voltage and frequency to break a selected chemical bond in a molecule. The reactor for carrying out such a process includes a chamber for containing the molecule and a generator for generating and applying the selected fast rise current.

MODULAR OZONE GENERATOR SYSTEM

An ozone generator system (1) in which a multitude of plate type ozone generators (2) are arranged adjacent to each other in a block (3). Each ozone generator comprises a chamber, adapted for converting oxygen to ozone by a corona discharge, and each chamber is provided with an inlet for oxygen or an oxygen-rich gas and an outlet for ozone. Said ozone generators are arranged in a block module (26) in which they are affixed by a block rack (4). Said block rack comprises an inlet port (5) adapted for introduction of oxygen gas, and an outlet port (6) adapted for discharge of ozone created through conversion within the generators comprised in the block module. A multitude of first conduits (7), each running between said inlet port and one chamber inlet, and a multitude of second conduits (8), each running between said outlet port and one chamber outlet, are provided within said block rack. Said conduits are arranged so that the flow distance between the inlet and outlet ports has the same ...

Multiple oxygen allotrope generator

An oxygen allotrope generator having a tube with an electrically grounded outer surface and an electrically positive inner surface. A plurality of corona reaction plates are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires and being in electrical connection with the electrically positive inner surface of the tube. An outer jacket encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections at the locations of the corona reaction.

OZONATED LIQUID DISPENSING UNIT

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. 1. A mobile system for producing and applying an ozonated liquid , comprising:a tank for holding water;an ozonated liquid dispensing unit, the ozonated liquid dispensing unit fluidly connected to the tank of water, the ozonated liquid dispensing unit comprising an ozone gas generator to generate ozone gas and an injector, and the injector injects ozone gas from the ozone gas generator into the water supplied to the ozonated liquid dispensing unit from the tank to form ozonated liquid;a reaction vessel fluidly connected to the ozonated liquid dispensing unit to receive the ozonated liquid from the ozonated liquid dispensing unit, the reaction vessel comprising a housing, the housing defining an interior, a first end comprising an entry port for the ozonated liquid, a second end comprising an exit port for the ozonated liquid, and a core positioned in the interior of the housing between the entry port and the exit port, and wherein the reaction vessel processes the ozonated liquid; and,an applicator in fluidic communication with the reaction vessel.2. The mobile system according to claim 1 , wherein the mobile system connects to a source of electricity.3. The mobile system according to claim 1 , the water is directed to a liquid input port of the ozonated liquid dispensing unit claim 1 , and the ozonated liquid is dispensed from a fluid exit opening of the ozonated liquid dispensing unit.4. The mobile system according to claim 1 , wherein the applicator sprays a mist of ozonated liquid.5. The mobile system according to claim 1 , further comprising a pump to transfer water from the tank to the ozonated liquid dispensing unit.6. The mobile system according to claim 1 , further comprising a pump claim 1 , a first fluid ...

MULTIPLE OXYGEN ALLOTROPE GENERATOR

An oxygen allotrope generator having a tube with an electrically grounded outer surface and an electrically positive inner surface. A plurality of corona reaction plates are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires and being in electrical connection with the electrically positive inner surface of the tube. An outer jacket encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections at the locations of the corona reaction. 1. An oxygen allotrope generator comprising:a tube having a wall of a predetermined thickness, said tube wall having an inner surface and an outer surface and having a first end and a second end;an inlet connected to said first end of said tube and adapted to be coupled to a source of oxygen-containing gas;a first electrically conductive element on the outer surface of said tube, said first element being adapted to be connected to ground;a second electrically conductive element on the inner surface of said tube;a conductor for connecting said second electrically conductive element to a source of electrical power;a tubular jacket surrounding said tube and being spaced from said tube wall by a predetermined distance;an outlet for oxygen allotrope-containing gas to exit from said jacket; anda plurality of spaced corona reaction plates across the interior of said tube, said corona reaction plates being electrically conductive and being electrically connected to said second electrically conductive element.2. The oxygen allotrope generator claim 1 , and further comprising a longitudinal central support wire interconnecting said corona reaction plates.3. The oxygen allotrope generator of claim 1 , and further comprising a plurality of corona reaction wires interconnecting said corona reaction plates.4. The oxygen allotrope generator of claim 1 , and further comprising a plurality of ...

A small-sized efficient ozone generator

본 발명은 판형상의 줄홈형 방전실을 설치하여 소형으로 고효율을 달성할 수 있게 하는 소형 고효율 오존발생장치에 관한 것으로서, 본 발명의 소형 고효율 오존발생장치는, 공기중의 산소가 산화되어 오존이 발생되도록 방전이 일어나는 방전실 및 상기 방전실에 고전압펄스를 인가하는 펄스발생기를 구비하여 이루어지는 오존발생장치를 구성함에 있어, 상기 방전실은, 수평으로 눕혀지고, 외부의 전선을 따라 고전압펄스가 인가되는 얇은 판상의 고전압전극과, 상판과 하판으로 이루어지고, 상기 고전압전극의 상면과 하면에 각각 위치하여 상기 고전압전극과 밀착되는 얇은 판상의 세라믹절연판 및 상기 방전실의 외관을 이루도록 상판과 하판으로 이루어지고, 상기 세라믹절연판을 둘러싸는 형상으로 밀봉 조립되며, 일측에 공기인입구와 타측에 공기배출구가 형성되고, 상기 공기인입구를 통과한 공기가 상기 공기배출구로 배출되도록 내면에 상기 세라믹절연판과 접촉하는 공기통로가 형성되며, 외부의 전선에 접지되는 판형상의 외장보조접지전극을 포함하여 이루어지는 것을 특징으로 하기 때문에 제품의 부피를 줄여 소형화할 수 있고, 설치 및 사용을 용이하게 하며, 제품의 제작비용을 절감할 수 있게 하고, 방전이 쉽게 일어나서, 자연공냉식으로도 충분히 냉각할 수 있고, 에너지 효율을 높게 하며, 작동이 매우 안정되고, 제품의 내구성을 향상시키게 하는 효과를 갖는다. The present invention relates to a small high-efficiency ozone generator for installing a plate-shaped row groove discharge chamber to achieve high efficiency with a small size. The small high-efficiency ozone generator of the present invention generates oxygen by oxidizing oxygen in air. In constructing an ozone generator comprising a discharge chamber in which discharge is generated and a pulse generator for applying a high voltage pulse to the discharge chamber, the discharge chamber is horizontally laid down, and the thin chamber in which the high voltage pulse is applied along an external wire is applied. It consists of a plate-shaped high voltage electrode, an upper plate and a lower plate, the upper plate and the lower plate so as to form an appearance of the thin plate-shaped ceramic insulating plate and the discharge chamber in close contact with the high voltage electrode, respectively located on the upper and lower surfaces of the high voltage electrode, Sealed and assembled in a shape surrounding the ceramic insulating plate, the air inlet on one side and the other side An air outlet is formed, and an air passage is formed on the inner surface to contact the ceramic insulating plate so that air passing through the air inlet is discharged to the air outlet, and includes a plate-shaped ...

Ozone system for multi-chamber tools

오존 농도를 제어하기 위해 개선된 시스템 및 방법이 멀티-챔버 툴과 연결된다. 시스템 및 방법은 오존 발생기와 조합된 제1 및 제2 농도 제어기를 포함한다. 제1 농도 제어기는 이벤트(EVENT)(즉, 멀티-챔버 툴의 챔버들중 하나가 온라인 또는 오프라인되는 것)를 검출하고 이에 응답하여 예측 제어 알고리즘에 따라 오존 발생기에 파워 명령을 제공한다. 제1 농도 제어기는 고속(즉, 약 1초) 응답 시간을 갖는다. 제2 농도 제어기는 이벤트중에 오존 발생기로부터 차단되나, 이벤트 이후에 경과되는 일정 시간 간격이 지나면 발생기를 제어한다. 제2 농도 제어기는 제1 농도 제어기보다 느린 응답 시간을 가지나, 제2 농도 제어기는 시스템에 긴 시간의 안정성을 제공하고 예측 제어 알고리즘에 업데이트된 데이터를 제공하는데 사용될 수 있다. Improved systems and methods for controlling ozone concentrations are associated with multi-chamber tools. The system and method include first and second concentration controllers in combination with ozone generators. The first concentration controller detects an event EVENT (ie, one of the chambers of the multi-chamber tool is online or offline) and in response provides a power command to the ozone generator in accordance with a predictive control algorithm. The first concentration controller has a high speed (ie, about 1 second) response time. The second concentration controller shuts off the ozone generator during the event, but controls the generator after a certain time interval that elapses after the event. The second concentration controller has a slower response time than the first concentration controller, but the second concentration controller can be used to provide long time stability to the system and provide updated data to the predictive control algorithm. 오존 농도, 오존 유량, 오존 시스템, 멀티-챔버 툴, Ozone concentration, ozone flow rate, ozone system, multi-chamber tool,

Ozone system for multi-chamber tools

Ozone generator

Corona discharge apparatus

Apparatus for generating high density ozone and waste water treatment apparatus using the same

The present invention relates to an apparatus for generating high density ozone, which comprises: an ozone generation unit comprising a reaction pipe where oxygen is supplied to, a first electrode separated from an inner wall of the reaction pipe and disposed in the reaction pipe, a second electrode disposed on an outer wall of the reaction pipe, and a discharging unit supplying power to induce discharge of the first electrode and the second electrode; and a connection pipe connecting a plurality of ozone generation units together.

Corona reaction system

A system for subjecting gas to high voltage corona wherein a gas is sequentially (serially) exposed to a plurality of corona generation zones. In a preferred system, the gas is conducted through several corona generators which are connected in series by gas conduits, and the gas within the system is cooled subsequent to each exposure to corona.

Device for generating ozone

Generator of multiple oxygen allotropes

Un generador de alótropos de oxigeno (101) que tiene un tubo (103) con una superficie eléctricamente conectada a un polo a tierra (104) y una superficie interior eléctricamente positiva (105). Una pluralidad de placas de reacción en cadena (116) están espaciadas a lo largo del interior del tubo, donde las placas están longitudinalmente interconectadas por alambres (17 , 118 , 121) y están en conexión eléctrica con la superficie interior del tubo eléctricamente positiva (109, 110). Una cubierta exterior (112) encierra el tubo y provee un segundo pase lineal para que el gas parcialmente ozonizado fluya en el generador. Una incorporación alternativa incluye conexiones de polo a tierra (108) externas distribuidas en las ubicaciones de la reacción de corona. An oxygen allotrope generator (101) having a tube (103) with a surface electrically connected to a grounded pole (104) and an electrically positive inner surface (105). A plurality of chain reaction plates (116) are spaced along the inside of the tube, where the plates are longitudinally interconnected by wires (17, 118, 121) and are in electrical connection with the inner surface of the electrically positive tube ( 109, 110). An outer cover (112) encloses the tube and provides a second linear pass for partially ozonized gas to flow into the generator. An alternative incorporation includes external pole-to-ground connections (108) distributed at the crown reaction locations.

CORONA DISCHARGE REACTION SYSTEM AND METHOD FOR CARRYING OUT REACTIONS BY CORONA DISCHARGE

Ozone generator

A concentric-tube type ozone generator wherein the lower end portion of the interior of the tube contains a supply of oil which contacts the inner side of the inner tube wall above the inner electrode to prevent the flow of creep currents between the inner and outer electrodes. A second supply of oil can be confined in the upper end portion of the inner tube wall above the inner electrode. The inner electrode may consist of a metallic foil which is biased against the inner side of the inner tube wall by a helical spring. The outer electrode may constitute a helically convoluted metallic wire. Two or more tubes can be mounted above each other with the outlet at the lower end of the upper tube in communication with the inlet at the upper end of the lower tube.

Ozonated liquid dispensing unit

A reaction vessel and an ozonated liquid dispensing unit are described herein. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The reaction vessel is incorporated into the unit to reduce bubbles of ozone gas and to break up bubbles of ozone gas in the ozonated liquid to provide a more effective and longer lasting cleaning and sanitizing solution.

Multiple oxygen allotrope generator

An oxygen allotrope generator (101) having a tube (103) with an electrically grounded outer surface (104) and an electrically positive inner surface (105). A plurality of corona reaction plates (116) are spaced along the interior of the tube, the plates being longitudinally inter-connected by wires (117, 118, 121) and being in electrical connection with the electrically positive (109, 110) inner surface of the tube. An outer jacket (112) encloses the tube and provides a second linear pass for partially ozonated gas to flow in the generator. An alternative embodiment includes external distributed ground connections (108) at the locations of the corona reaction.

Corona reactor method and apparatus

An improved corona reactor method and apparatus for subjecting a fluid reactant to a corona discharge, and particularly for generating ozone. The corona reactor includes a housing containing an air-cooled, modular, corona reactor core comprising a plurality of separate, individually removable, air-tight corona reactor cells. Each corona reactor cell includes two, spacedapart, metallic electrodes or shell portions defining an airtight corona discharge chamber therebetween. The exterior surfaces of the electrodes are bare and exposed to ambient; the interior (facing) surfaces are covered with a ceramic dielectric; and the fluid reactant is subjected to the corona discharge within the corona discharge chamber by appropriate inlet and outlet ports. The individual cells are electrically connected in series.

Ozone generator

An ozone generator ( 1 ) is presented comprising a body ( 2 ), a first electrode ( 4 ), a second electrode ( 6 ), an elongate channel within the body extending between the first and second electrodes, an inlet ( 10 ) and an outlet ( 12 ); the elongate channel being in fluid communication with the inlet and the outlet; the elongate channel isolated from each of the first and second electrodes by a respective dielectric layer ( 22, 24 ), whereby an electric field can be generated across the elongate channel between the first and second electrodes. The presented ozone generator allows small quantities of ozone to be produced for use in small scale water treatment. In addition, a method of producing ozone is presented using an ozone generator according to the invention.

Ozone generator with a generally spherical corona chamber

This invention relates to a novel ozone generator device for the production of high concentrations of ozone by way of a design that permits a process environment that is consonant with the optimum values of hardware and operating variables that thermodynamically favor the production of ozone. The device is characterized by a small corona chamber resulting in a low oxygen retention time, a thermally conductive ducted core permitting circulation of a coolant for cooling the feed oxygen and produced ozone, a spherical corona chamber and electrode geometry promoting a homogeneous high electric field density, operating pressures as high as 2000 psi, free expansion cooling of the oxygen at both the inlet and outlet ports of the device, and the selection of an electrode that ensures the production and maintenance of a homogeneous corona. Also disclosed is a closed-loop ozone generator system wherein unused feed oxygen is recovered and recycled for further processing by the system. Uses of the ozone generator device of this invention is more diverse than uses described in the background by virtue of the increased ozone production of the device over the background art, and includes remediation of biofoulants, biocontaminants, chlorine, chloramines and organic contaminants from drinking and process water, and the removal of sulfur dioxide and nitrogen dioxide from flue gases.

CORONAREAKTOR.

Patent NO132349C

N-phase ozone generator

A compact, inexpensive, large-capacity ozone generator with increased ease of apparatus maintenance. An ozone power supply includes an n-phase inverter for obtaining an AC voltage having a predetermined frequency and outputting an n-phase AC voltage waveform; n reactors and an n-phase transformer for converting an n-phase AC voltage to a high AC voltage; n high-voltage terminals for outputting the n-phase high AC voltage; and a low-voltage terminal having a common potential. Ozone generator units are electrically divided into n pieces within a discharge chamber. Each ozone generator unit includes n high-voltage electrode terminals and one low-voltage electrode terminal, common to all ozone generator units. Each ozone generator unit supports an n-phase AC discharge to generate ozone.

Process and apparatus for chemical conversion

A process and reactor for chemical conversion is taught. The process allows the selective breaking of chemical bonds in a molecule by use of fast rise alternating current or fast rise pulsed direct current, each fast rise portion being selected to have a suitable voltage and frequency to break a selected chemical bond in a molecule. The reactor for carrying out such a process includes a chamber for containing the molecule and a generator for generating and applying the selected fast rise current.

Ozonated liquid dispensing unit

A ozonated liquid dispensing unit is described. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The unit includes a liquid input port to receive liquid into the unit. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with the liquid input port. The injector in supply communication with the second dielectric cell for receiving the ozone gas from the second dielectric cell, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid input port to produce an ozonated liquid. A liquid output port discharges the ozonated liquid from the unit. A faucet or spray may be used to control the discharge of the ozonated liquid from the unit.

Ozonated liquid dispensing unit

A ozonated liquid dispensing unit is described. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The unit includes a liquid input port to receive liquid into the unit. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with the liquid input port. The injector in supply communication with the second dielectric cell for receiving the ozone gas from the second dielectric cell, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid input port to produce an ozonated liquid. A liquid output port discharges the ozonated liquid from the unit. A faucet or spray may be used to control the discharge of the ozonated liquid from the unit.

Modular ozone generator system

An ozone generator system ( 1 ) in which a multitude of plate type ozone generators ( 2 ) are arranged adjacent to each other in a block ( 3 ). Each ozone generator comprises a chamber, adapted for converting oxygen to ozone by a corona discharge, and each chamber is provided with an inlet for oxygen or an oxygen-rich gas and an outlet for ozone. Said ozone generators are arranged in a block module ( 26 ) in which they are affixed by a block rack ( 4 ). Said block rack comprises an inlet port ( 5 ) adapted for introduction of oxygen gas, and an outlet port ( 6 ) adapted for discharge of ozone created through conversion within the generators comprised in the block module. A multitude of first conduits ( 7 ), each running between said inlet port and one chamber inlet, and a multitude of second conduits ( 8 ), each running between said outlet port and one chamber outlet, are provided within said block rack. Said conduits are arranged so that the flow distance between the inlet and outlet ports has the same length, regardless of which generator the introduced gas passes through, thereby achieving an even gas pressure and gas flow, through parallel connection of the generators.

Apparatus for highly efficient cold-plasma ozone production

An apparatus comprising a cold-plasma ozone generator, the ozone generator comprising: a non-arcing non-coronal ozone production cell capable of generating ozone; the ozone production cell having a pair of electrodes placed on two sides of the production cell and spaced apart by an electrode gap, and a dielectric layer on each of the electrodes facing inward into the ozone production cell; a high-voltage pulse generator attached to the electrodes and configured for producing a glow discharge cold plasma between the electrodes, the high-voltage pulse generator being able to produce sufficient voltage to generate the glow discharge cold plasma; a cooling system attached to each of the electrodes; and an oxygen source adapted to provide gas flow through the production cell in the gap between the pair of electrodes that efficiently generates ozone in the cold plasma, wherein the dielectric layers are intimately and directly bonded to each of the electrodes.

用于臭氧发生器的地电极

本发明提供一种用于臭氧发生器的地电极，包括具有第一表面、第二表面、第一侧边和第二侧边的板体和在所述板体内部形成的冷却流体通道；所述板体具有在所述第一表面和第二表面中的至少一个内的用于紧贴高压放电装置的接触面、从所述接触面下凹形成的至少一个微气道、位于第一侧边的第一纵向气槽和位于第二侧边的第二纵向气槽；其中，所述微气道从所述第一纵向气槽曲折延伸至所述第二纵向气槽。本发明还提供一种用于臭氧发生器的地电极组、板式臭氧发生模组以及臭氧发生器。

Modulares ozon herstellungssystem

一种臭氧发生装置

本发明公开了一种臭氧发生装置，在进气室、冷却室、出气室、反应通道、放电单元、第一进液口和第一出液口的基础上，增加了设于进气室与冷却室之间的第一隔离腔和设于出气室与冷却室之间的第二隔离腔、套设于反应通道上的隔离通道、设于第一隔离腔与第二隔离腔中的其中一个上的第二进液口和设于其中另一个上的第二出液口，隔离通道两端分别与第一隔离腔和第二隔离腔连通，隔离通道内表面与反应通道外表面之间设有用于供第二冷却液通过的间隙。本发明的一种臭氧发生装置，将在第一隔离腔、间隙和第二隔离腔中流通的第二冷却液与第一冷却液进行间接换热，避免了腐蚀性强的第一冷却液与反应通道直接接触，提高了设备安全性和使用寿命。

一种臭氧发生装置

本发明公开了一种臭氧发生装置，在进气室、冷却室、出气室、反应通道、放电单元、第一进液口和第一出液口的基础上，增加了设于进气室与冷却室之间的第一隔离腔和设于出气室与冷却室之间的第二隔离腔、套设于反应通道上的隔离通道、设于第一隔离腔与第二隔离腔中的其中一个上的第二进液口和设于其中另一个上的第二出液口，隔离通道两端分别与第一隔离腔和第二隔离腔连通，隔离通道内表面与反应通道外表面之间设有用于供第二冷却液通过的间隙。本发明的一种臭氧发生装置，将在第一隔离腔、间隙和第二隔离腔中流通的第二冷却液与第一冷却液进行间接换热，避免了腐蚀性强的第一冷却液与反应通道直接接触，提高了设备安全性和使用寿命。

Process and apparatus for chemical conversion

A process and reactor for chemical conversion is taught. The process allows the selective breaking of chemical bonds in a molecule by use of fast rise alternating current or fast rise pulsed direct current, each fast rise portion being selected to have a suitable voltage and frequency to break a selected chemical bond in a molecule. The reactor (500) for carrying out such a process includes a chamber (514) for containing the molecule and a generator for generating and applying the selected fast rise current.

一种新型的臭氧发生器模块单元

本发明公开了一种模块化板式臭氧发生器水冷单元，属于臭氧发生器设备领域，包括导热片、地电极、固定在地电极上的陶瓷介电体、把导热片和地电极压紧的螺栓。通过地电极两面均可通导热片两面贴面拼装的方式，使每个水冷单元的臭氧放电面积占比大大提高，同时通过增厚地电极厚度，加大冷却水过流通道的流量，两者结合使臭氧浓度和臭氧量大大提升。

고순도 오존발생장치 및 이를 이용한 고순도 오존발생방법

본 발명은 고순도 오존발생장치에 있어서, 외부로부터 압축공기를 공급받아 고농도 산소를 발생시키도록 구성되는 산소발생수단; 상기 산소발생수단과 연결되어 내부로 고농도 산소가 유입되도록 형성되는 케이스부; 상기 케이스부의 내부에 다수개가 구비됨과 아울러 각각은 케이스부로부터 탈부착 가능한 모듈 형태로 형성되며, 각각에는 서로 이격됨과 아울러 원형의 관 형태를 갖는 다수의 제1전극부가 구비되고, 제1전극부의 전후방에는 평판형으로 형성됨과 아울러 내측에 다수의 관통된 통공이 형성되어 제1전극부의 전후방이 각각 결합되는 플레이트가 구비되며, 제1전극부 각각의 내측에는 제1전극부와 이격됨과 아울러 단면이 다각형으로 형성되어 제1전극부 전후방으로 연장되는 제2전극부가 삽입 구비되고, 플레이트와 이격된 제2전극부의 전후방에는 각각 내측으로 고농도 산소가 지나갈 수 있는 통로가 형성됨과 아울러 제2전극부의 전후방이 각각 고정되는 사각형상의 프레임이 구비되며, 프레임 한 쌍의 모서리에는 각각 프레임에 고정됨과 아울러 프레임이 마주하는 방향으로 연장되어 플레이트를 관통 고정하는 연결구가 구비되는 오존발생수단; 상기 케이스부의 일측에 설치되어 오존발생수단의 제1,2전극부로 고전압을 공급하여 코로나 방전이 발생하도록 하는 고전압 전원공급수단;을 포함하여 이루어짐을 특징으로 한다. 또한, 본 발명은 고순도 오존발생장치를 이용한 고순도 오존발생방법에 있어서, 상기 산소발생수단 내부로 압축공기를 공급시켜 고농도 산소를 발생시키는 고농도 산소생성단계; 상기 산소발생수단에 의해 발생된 고농도 산소를 케이스부 내부로 공급하는 고농도 산소공급단계; 상기 케이스부 내부로 고농도 산소가 공급되면 고전압 전원공급수단을 통해 오존발생수단의 제1,2전극부로 고전압을 공급하는 고전압 공급단계; 상기 고전압 전원공급수단을 통해 공급되는 고전압으로 오존발생수단의 제1,2전극부가 코로나 방전시 고전압 무성방전에 의한 오존이 발생되는 고순도 오존생성단계; 상기 오존생성단계에 의해 발생된 고순도 오존을 산업시설로 배출시키는 배출단계; 로 이루어짐을 특징으로 한다.

一种臭氧发生器的放电模块

本发明提供一种臭氧发生器的放电模块，包括：高压电极板、地电极板、绝缘板、密封垫，这些零件层叠组合为放电模块，放电模块可以用于组装臭氧发生器的放电室。其工作原理是：氧气流入放电模块的气体入口，然后穿过绝缘板和地电极板之间的间隙，氧气在间隙内被高压电离生成臭氧，臭氧从放电模块的气体出口流出。这种高度集成的叠加结构使得放电模块的体积大幅缩小、重量更轻、效率更高，独特的叠加式结构可以自由配置单机产量，统一规格的零件更适合标准化批量生产，使用这种放电模块的样机的额定臭氧浓度达到200mg/L，臭氧电耗低到6kWh/kg，主要指标超越行业同类产品。因此，它在创新性、经济性、灵活性、标准化方面有显著优势。

オゾン発生装置およびその製造方法

オゾン発生装置およびその製造方法

　小型化が容易であり、低電圧で駆動することができるオゾン発生装置を実現する。そのため、オゾン発生装置（１）は、基板（２）と２つの駆動電極（３Ａ，３Ｂ）とを備える。基板（２）は、第１主面と第２主面とを有し、第１主面と第２主面との間を貫通する３つの放電孔（２Ａ，２Ｂ，２Ｃ）が形成されている。２つの駆動電極（３Ａ，３Ｂ）は、３つの放電孔（２Ａ，２Ｂ，２Ｃ）に対向するとともに、互いに対向している。３つの放電孔（２Ａ，２Ｂ，２Ｃ）は、部分的に径が小さい狭隘部（２Ａ１，２Ｂ１，２Ｃ１）を備えている。

Ozongenerator

Ein Ozongenerator weist ein Gehäuse (14), das einen inneren Hohlraum (11) hat, und eine Vielzahl von Elektrodenpaaren (16) auf, die sich im inneren Hohlraum (11) befinden. Die Elektrodenpaare (16) enthalten jeweils zwei Elektroden (20), die in einem Abstand einer vorbestimmten Spaltlänge angeordnet sind, und zwischen den zwei Elektroden (20) ist ein Entladungsraum (22) ausgebildet, wodurch Ozon produziert wird, wenn zumindest zwischen den zwei Elektroden (20) ein Ausgangsgas (12) strömt und zwischen den zwei Elektroden (20) eine Entladung erzeugt wird. Der Ozongenerator hat in einem beliebigen Querschnitt (36), der eine Normalenrichtung hat, die parallel zu einer Hauptströmungsrichtung des Ausgangsgases (12) im inneren Hohlraum (11) ist, einen Nichtentladungsabschnitt (37).

オゾン発生器

【課題】使用環境の湿度が高くなっても、オゾン発生の変化が少なく、幅広い湿度環境において安定したオゾン発生を得ることができるオゾン発生器を提供する。 【解決手段】筐体１４の中空部１１内に２つの電極２０が所定のギャップ長Ｄｇを隔てて配置された複数の電極対１６が配置され、電極対１６の少なくとも２つの電極２０間に原料ガス１２を通過させ、２つの電極２０間に放電を発生させることでオゾンを発生させるオゾン発生器において、２つの電極２０で挟まれた空間が放電空間２２であり、中空部１１における原料ガス１２の流れの主方向を法線方向とする任意の断面３６に、放電空間ではない部分３７が存在する。 【選択図】図４

オゾン発生装置およびその製造方法

小型化が容易であり、低電圧で駆動することができるオゾン発生装置を実現する。そのため、オゾン発生装置（１）は、基板（２）と２つの駆動電極（３Ａ，３Ｂ）とを備える。基板（２）は、第１主面と第２主面とを有し、第１主面と第２主面との間を貫通する３つの放電孔（２Ａ，２Ｂ，２Ｃ）が形成されている。２つの駆動電極（３Ａ，３Ｂ）は、３つの放電孔（２Ａ，２Ｂ，２Ｃ）に対向するとともに、互いに対向している。３つの放電孔（２Ａ，２Ｂ，２Ｃ）は、部分的に径が小さい狭隘部（２Ａ１，２Ｂ１，２Ｃ１）を備えている。

Ozonated liquid dispensing unit

A ozonated liquid dispensing unit is described. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The unit includes a liquid input port to receive liquid into the unit. The unit includes a first dielectric cell for producing ozone gas from ambient air and a second dielectric cell for producing ozone gas. The first dielectric cell is in supply communication with the second dielectric cell for supplying the second dielectric cell with a supply gas containing the ozone gas generated from the ambient air. The second dielectric cell produces ozone gas from the supply gas. An injector is in fluidic communication with the liquid input port. The injector in supply communication with the second dielectric cell for receiving the ozone gas from the second dielectric cell, and the injector mixes the ozone gas from the second dielectric cell with the liquid from the liquid input port to produce an ozonated liquid. A liquid output port discharges the ozonated liquid from the unit. A faucet or spray may be used to control the discharge of the ozonated liquid from the unit.

Segmented and maintainable ozone generator

The present inventions relates to an ozone generator (1) having a housing (4) which has an outer casing and a first end face (21) and a second end face (30), the outer casing and the two end faces delimiting an interior space, and the end faces each having a number of mounting openings (31) into each of which an elongate electrode assembly (20) is inserted in such a way that electrode assembly extends from one mounting opening in the first end face to an opposite mounting opening in the second end face and respectively seal the two mounting openings, wherein the electrode assemblies (20) in each case constitute an ozone generator segment (2, 3, 20), each segment (2, 3, 20) comprising a number of individual electrodes which are arranged so that a gas flow through the electrodes (20) of a segment is achievable in parallel, and that each segment is provided with a gas inlet port (2a, 3a, 20a) and a gas outlet port (2b, 3b 20b).

Segmented and maintainable ozone generator

The present inventions relates to an ozone generator 1 having a housing 4 which has an outer casing and a first end face 21 and a second end face 30, the outer casing and the two end faces delimiting an interior space, and the end faces each having a number of mounting openings 31 into each of which an elongate electrode assembly 20 is inserted in such a way that electrode assembly extends from one mounting opening in the first end face to an opposite mounting opening in the second end face and respectively seal the two mounting openings, wherein the electrode assemblies 20 in each case constitute an ozone generator segment 2, 3, 20, each segment 2, 3, 20 comprising a number of individual electrodes which are arranged so that a gas flow through the electrodes 20 of a segment is achievable in parallel, and that each segment is provided with a gas inlet port 2a, 3a, 20a and a gas outlet port 2b, 3b 20b.

Ozone generator

An ozone generator includes one or more electrode pairs each containing two electrodes arranged at a distance of a predetermined gap length and a power source for applying an alternating-current voltage between the two electrodes. In the ozone generator, ozone is produced when a source gas flows at least between the two electrodes and a discharge is generated between the two electrodes. The ozone generator has a discharge space formed between the two electrodes, and the ozone generator satisfies the condition of 0.5<V/f/L wherein V (m/s) represents a flow velocity of the source gas flowing through the discharge space, f (Hz) represents a frequency of the alternating-current voltage, and L (m) represents a length of the discharge space in the main flow direction of the source gas.

Ozonated liquid dispensing unit

A reaction vessel and an ozonated liquid dispensing unit are described herein. The unit produces and dispenses an ozonated liquid that may be used to clean and sanitize a variety of articles or used in conjunction with cleaning processes and other apparatus. The reaction vessel is incorporated into the unit to reduce bubbles of ozone gas and to break up bubbles of ozone gas in the ozonated liquid to provide a more effective and longer lasting cleaning and sanitizing solution.

Ozone generator

An ozone generator includes one or more electrode pairs each containing two electrodes arranged at a distance of a predetermined gap length. In the ozone generator, ozone is produced when a source gas flows at least between the two electrodes and a discharge is generated between the two electrodes. Each electrode contains a tubular dielectric body having a hollow portion and a conductive body disposed in the hollow portion. The gap length is less than 1.0 mm.

オゾン発生器

【課題】放電によって発生したオゾンが、再び放電にさらされるということが抑制され、Ｏ原子との反応による分解反応や、水分子やＯＨとの反応による分解反応が起き難く、オゾン発生の低減を少なくすることができるオゾン発生器を提供する。 【解決手段】２つの電極が所定のギャップ長を隔てて配置された１以上の電極対と、２つの電極間に交流電圧を印加する電源とを有し、電極対の少なくとも２つの電極間に原料ガスを通過させ、２つの電極間に放電を発生させることで、オゾンを発生させるオゾン発生器において、２つの電極で挟まれた空間が放電空間であり、放電空間を通過する原料ガスの流速をＶ（ｍ／ｓ）、交流電圧の周波数をｆ（Ｈｚ）、放電空間のうち、原料ガスの流れの主方向に沿った長さをＬ（ｍ）としたとき、０．５＜Ｌ／Ｖ／ｆを満足する。 【選択図】図３

ｎ상 오존 생성장치

본 발명은 컴팩트하고 저렴하며 장비 관리의 용이성을 증대할 수 있는 대용량 오존 발생장치를 제공한다. 오존 전원은 소정 수파수의 교류 전압으로 변환된 n상의 교류 전압 파형을 출력하는 n상 인버터(4000)와, n상의 교류 전압을 n상의 고전압 교류 전압으로 변환하는 n개의 반응기(2000-a) 및 n상의 변환기(2000-b)와, n상의 고전압 교류 전압을 출력하는 n개의 고전압 단자와, 공통 전위를 가지는 1개의 저전압 단자로 구성된다. 복수 개의 오존 발생기 유니트(100)는 방전 챔버 내에서 n개로 전기적으로 분할되고 각각의 오존 발생기로부터 n개의 고압 전극 단자와 오존 발생기 유니트의 전체의 저압 전극을 공통으로 하는 1개의 저압 전극 단자를 인출하고, n개의 고전압 단자에 n개의 고압 전극 단자를 접속하며 1개의 저전압 단자에 1개의 저전압 전극 단자와 접속하는 것에 의해 n상의 교류 방전을 각 오존 발생 유니트에 발생하고 오존을 발생한다. 오존 발생기, 인버터, 반응기, 변환기

用于臭氧发生器的地电极

本发明提供一种用于臭氧发生器的地电极，包括具有第一表面、第二表面、第一侧边和第二侧边的板体和在所述板体内部形成的冷却流体通道；所述板体具有在所述第一表面和第二表面中的至少一个内的用于紧贴高压放电装置的接触面、从所述接触面下凹形成的至少一个微气道、位于第一侧边的第一纵向气槽和位于第二侧边的第二纵向气槽；其中，所述微气道从所述第一纵向气槽曲折延伸至所述第二纵向气槽。本发明还提供一种用于臭氧发生器的地电极组、板式臭氧发生模组以及臭氧发生器。

一种臭氧发生器的放电模块

本发明提供一种臭氧发生器的放电模块，包括：高压电极板、地电极板、绝缘板、密封垫，这些零件层叠组合为放电模块，放电模块可以用于组装臭氧发生器的放电室。其工作原理是：氧气流入放电模块的气体入口，然后穿过绝缘板和地电极板之间的间隙，氧气在间隙内被高压电离生成臭氧，臭氧从放电模块的气体出口流出。这种高度集成的叠加结构使得放电模块的体积大幅缩小、重量更轻、效率更高，独特的叠加式结构可以自由配置单机产量，统一规格的零件更适合标准化批量生产，使用这种放电模块的样机的额定臭氧浓度达到200mg/L，臭氧电耗低到6kWh/kg，主要指标超越行业同类产品。因此，它在创新性、经济性、灵活性、标准化方面有显著优势。

陶瓷片臭氧发生器

本发明涉及臭氧制造附属装置的技术领域，特别是涉及一种陶瓷片臭氧发生器，可便于对冷却筒内壁上的水垢进行清理；包括箱体、四组支腿、冷却筒、第一陶瓷片和第二陶瓷片，箱体内部设置有工作腔，箱体左端设置有箱口，并在箱口处可拆卸设置有箱盖，冷却筒左侧壁和右侧壁中央区域分别连通设置有入水管和出水管，箱盖左侧壁上半区域和下半区域分别连通设置有第一出气管和第二出气管，箱体右侧壁上半区域和下半区域分别连通设置有第一进气管和第二进气管，箱体顶端和底端分别设置有第一外电极和第二外电极，第一陶瓷片和第二陶瓷内分别设置有第一内电极和第二内电极；还包括电机、连接板、固定杆和刮板，电机右部输出端设置有传动轴。

一种臭氧发生单元

本发明提供一种臭氧发生单元，包括多个叠置的板式地电极、多个高压放电单元以及分别连接至所述多个高压电极板单元的多个高压保险装置，其中高压放电单元包括高压电极板组件和位于高压电极板组件两侧面的介质板。本发明还提供一种具有该臭氧发生单元的臭氧发生器。

一种用于臭氧发生器的高压电极板组件

本发明提供一种用于臭氧发生器的高压电极板组件，其特征是，包括位于中间的弹性垫板和两侧的一对高压电极板，其中该弹性垫板包括板体和与所述板体一体形成的接头部，其中该弹性垫板还包括被所述接头部保持且从该接头部的顶部延伸出的接线端以及与该接线端电连接或成一体的一对末端，还设置有与该对末端机械连接的一对弹性接触片，该对高压电极板各自具有槽口，该对弹性接触片延伸穿过该对高压电极板的槽口以与该对高压电极板电连接且将其夹持在所述弹性垫板上。本发明还提供一种高压放电单元。

臭氧发生器单元和系统

本公开旨在提供一种臭氧发生器单元。本公开还旨在提供一种臭氧发生器系统。本公开旨在提供对臭氧发生器的压力变化和冷却的现有问题的解决方案。本公开的目的是提供至少部分地克服现有技术中遇到的问题的解决方案，并提供用于气流的均匀流动以及用于臭氧发生器的有效冷却的解决方案。公开了一种臭氧发生器单元。该臭氧发生器单元包括壳体(102)。壳体包括具有第一凹部(204)的第一半部(104)和具有第二凹部(206)的第二半部(106)。该臭氧发生器单元还包括壳体中的入口(202)和出口(110)，布置在第一凹部内并与第一半部的内表面(240)接触的第一介电盘(210)、布置在第二凹部内并与第二半部的内表面(242)接触的第二介电盘(214)，以及具有气体通道(220)并布置在第一介电盘与第二介电盘之间的高压电极(218)。高压电极使用第一间隔件(230)和第二间隔件(232)与第一介电盘和第二介电盘间隔开，以在高压电极的两侧上构成第一气体腔室(250)和第二气体腔室(252)。

Method for generating ozone

An ozone generator includes one or more electrode pairs each containing two electrodes arranged at a distance of a predetermined gap length and a power source for applying an alternating-current voltage between the two electrodes. In the ozone generator, ozone is produced when a source gas flows at least between the two electrodes and a discharge is generated between the two electrodes. The ozone generator has a discharge space formed between the two electrodes, and the ozone generator satisfies the condition of 0.5<V/f/L wherein V (m/s) represents a flow velocity of the source gas flowing through the discharge space, f (Hz) represents a frequency of the alternating-current voltage, and L (m) represents a length of the discharge space in the main flow direction of the source gas.