In situ plant vigor machine

Plant vigor machines and methods for enhancing plant vigor are disclosed. The machine comprises a corona discharge cell to create an electrical discharge across an air gap. An electrode to generate copper ions. An air conveyance mechanism to pass air through the corona discharge cell to produce enriched air combined with the copper ions wherein the enriched air comprises oxygen O 2 and nitrogen dioxide NO 2 . An air infuser mechanism to infuse water with the enriched air combined with the copper ions to create enriched water wherein the enriched water comprises the oxygen O 2 , the copper ions, and nitrate radical NO 3 . A water conveyance mechanism couple with the air infuser to convey the water to air infuser mechanism and to convey the enriched water away from the air infuser mechanism to a plant to enhance a vigor of the plant.

Ozonized biochar: phosphorus sustainability and sand soilization

Surface-oxygenated biochar compositions and sonication-ozonization methods create advanced hydrophilic biochar materials having higher cation exchange capacity, optimized pH, improved wettability, and toxin free components. These sonicated and ozonized biochar compositions are used as filtration materials for clean water and air, as phosphorus solubilizing reagents to mix with phosphate rock materials to make a slow-releasing phosphate fertilizer, as biochar soil additives to help solubilize phosphorus and reduce phosphorus fertilizer additions required to achieve desired soil phosphorus activity, crop uptake, and yield goals, as sand soilization reagents by utilizing their liquid gel-forming activity in the spaces among sand particles to retain water and nutrients and hold the sand particles together, as plant growth stimulants by using the humic acids-like surface-oxygenated biochar substances at a proper ppm concentration and as carbon sequestration agents to help control climate change for energy and environmental sustainability on Earth.

METHOD AND DEVICE FOR GENERATING A NON-THERMAL PLASMA HAVING A PREDETERMINED OZONE CONCENTRATION

A method for generating a non-thermal plasma having predetermined ozone concentration includes: providing an at least approximately closed volume as a reaction region; activating a plasma source and generating a non-thermal plasma in the reaction region. The plasma is held in the reaction region at least until a predetermined ozone concentration is reached or the ozone concentration falls below a predetermined upper limit for the ozone concentration. 1. A method for generating a non-thermal plasma having predetermined ozone concentration , the method comprising:providing an at least approximately closed volume as a reaction region; andactivating a plasma source and generating a non-thermal plasma in the reaction region,in which the plasma is held in the reaction region at least until a predetermined ozone concentration is reached or the ozone concentration falls below a predetermined upper limit for the ozone concentration.2. The method of claim 1 , wherein the plasma source is kept activated until claim 1 , after passing through a maximum of the ozone concentration in the reaction region claim 1 , the predetermined ozone concentration is reached or the ozone concentration falls below the predetermined upper limit for the ozone concentration claim 1 , wherein the maximum of the ozone concentration has a value which is greater than the predetermined ozone concentration or the predetermined upper limit for the ozone concentration.3. The method of claim 1 , wherein the plasma source is kept activated until a predetermined ratio of the ozone concentration to a nitrogen oxide concentration is reached.4. The method of claim 1 , wherein the non-thermal plasma is used for disinfection and/or sterilization and/or assistance of wound healing.5. The method of claim 1 , wherein the plasma is transferred from the reaction region into an active region set apart from the reaction region after the predetermined ozone concentration is reached or the ozone concentration falls below ...

SYSTEMS AND METHODS FOR GENERATING OZONE

An ozone generating cell includes a corona discharge chamber with a curved side wall. The cell includes a high-voltage electrode, a ground electrode, and a dielectric material positioned between the high-voltage electrode and the ground electrode. The cell includes a gas channel formed between the dielectric material and the ground electrode. The channel has a first end in fluid communication with a gas opening in the dielectric material, which is in fluid communication with a gas port. The channel has a second end in fluid communication with another gas port. The channel further includes multiple concentric segments between the first and second ends of the channel. 1. An ozone generating cell , comprising:a. a first gas port;b. a second gas port;c. a power connection; and i. a curved side wall;', 'ii. a high-voltage electrode electrically coupled to the power connection;', 'iii. a ground electrode;', 'iv. a dielectric material comprising a gas opening in fluid communication with the first gas port, the dielectric material positioned between the high-voltage electrode and the ground electrode; and', a) a first end in fluid communication with the gas opening in the dielectric material;', 'b) a plurality of concentric segments; and', 'c) a second end in fluid communication with the second gas port., 'v. a gas channel formed between the dielectric material and the ground electrode, the gas channel comprising], 'd. a corona discharge chamber comprising2. The ozone generating cell of claim 1 , wherein the curved side wall forms a cylindrical side wall of the corona discharge chamber.3. The ozone generating cell of claim 1 , wherein the ground electrode is connected to the curved side wall and forms an end wall of the corona discharge chamber.4. The ozone generating cell of claim 1 , further comprising one or more channel walls claim 1 , wherein the gas channel is defined by the dielectric material claim 1 , the one or more channel walls claim 1 , and the ground electrode ...

OZONE GENERATING DEVICE, AIR CONDITIONING DEVICE, AND VEHICLE

An ozone generating device including an excimer lamp having an arc tube containing a luminescent gas, a first electrode, and a second electrode. The arc tube has a first end portion and a second end portion, a first diameter-reduced portion provided continuously from the first end portion, a diameter of which decreases as a distance from the first end portion increases, and a second diameter-reduced portion provided continuously from the second end portion, a diameter of which decreases as a distance from the second end portion increases, the first electrode is provided for an outer periphery surface of the first end portion, the second electrode is provided for an outer periphery surface of the second end portion, the arc tube is fixed via the cylindrical portion, and the first electrode is not provided over the first diameter-reduced portion, and/or the second electrode is not provided over the second diameter-reduced portion. 1. An ozone generating device , comprising:an excimer lamp having an arc tube in which a luminescent gas is enclosed, a first electrode, and a second electrode, whereinthe arc tube includes a cylindrical portion having a first end portion and a second end portion, a first diameter-reduced portion provided continuously from the first end portion, a diameter of which decreases as a distance from the first end portion increases, and a second diameter-reduced portion provided continuously from the second end portion, a diameter of which decreases as a distance from the second end portion increases,the first electrode is provided for an outer periphery surface of the first end portion,the second electrode is provided for an outer periphery surface of the second end portion,the arc tube is fixed via the cylindrical portion, andthe first electrode is not provided over the first diameter-reduced portion, and/or the second electrode is not provided over the second diameter-reduced portion.2. The ozone generating device according to claim 1 , ...

OZONE GENERATOR WITH POSITION-DEPENDENT DISCHARGE DISTRIBUTION

An ozone generator includes a high-voltage electrode and at least one counter electrode, which define an interstice in which at least one dielectric is arranged and through which a gas flows in the flow direction. The high-voltage electrode and the at least one counter electrode are provided with a connection for an electrical voltage supply to generate corona discharges which are discharged from surface discharge locations. The mean sparking distance and the mean spacing between the high-voltage electrode and the at least one counter-electrode are constant. The number of surface discharge locations decreases in the flow direction. 18.-. (canceled)9. An ozone generator comprising:a high-voltage electrode;at least one counter electrode;an interstice configured to support a flow of gas in a flow direction between the high-voltage electrode and the at least one counter electrode, the interstice having at least one dielectric therein, the interstice defining a constant mean sparking distance and a constant mean spacing between the high-voltage electrode and the at least one counter-electrode;an electrical voltage supply connected to the high-voltage electrode and the at least one counter electrode; andone or more surface discharge locations configured to produce corona discharges, the number of surface discharge locations decreasing in the flow direction.10. The ozone generator according to claim 9 , wherein the number of surface discharge locations continuously decreases in the flow direction.11. The ozone generator according to claim 9 , wherein the surface discharge locations are arranged on the high-voltage electrode.12. The ozone generator according to claim 11 , wherein the high-voltage electrode comprise a mesh claim 11 , braid claim 11 , knit claim 11 , weave claim 11 , or winding of wire that defines said surface discharge locations.13. The ozone generator according to claim 12 , wherein the wire defines a mesh having a mesh width claim 12 , wherein the mesh ...

Ozone Generator

An ozone generator is contained in a housing having a fan for inducing air flow through the housing and over an ozone generating plate where atmospheric oxygen is electrochemically converted to ozone, which flows out of the housing through a grid opening. The ozone generating plate is defined by a glass plate having electrically conductive grids on both sides thereof and each grid is electrically powered to create corona discharge from the conductor; as air and oxygen in the air flows over the plate it is converted to ozone. 1. An ozone generator , comprising:a housing having an inlet and an outlet and a passageway therebetween;a fan;a power source;an ozone generator in the passageway, the ozone generator defined by a glass plate having opposed first and second sides, a first metallic grid attached to the first side of the plate and a second metallic grid attached to the second side of the plate;a first conductor electrically connected to the power source and to the first metallic grid; anda second conductor electrically connected to the power source and to the second metallic grid.2. The ozone generator according to including first and second non-conductive insulating blocks in the housing claim 1 , wherein the ozone generator is mounted to the first and second non-conductive insulating blocks and is thereby supported in the passageway3. The ozone generator according to wherein each of the first and second non-conductive insulating blocks includes an elongate slot formed in a face of said blocks and wherein the glass plate has opposed first and second side edges and the first and second side edges of the glass plate are received in the elongate slots formed in the respective first and second non-conductive insulating blocks.4. The ozone generator according to in which a first end of the first conductor is attached to the first non-conducting insulating block and a second end of the first conductor is in electrical contact with the first metallic grid claim 3 , and ...

OZONE-GENERATING SYSTEM AND OZONE GENERATION METHOD

A system including: an ozone generating device including discharge electrodes forming a discharge space; a gas supplying device; a power source device that supplies power to the discharge electrodes; a temperature adjustment device that adjusts temperature of the discharge electrodes; a control unit that controls the ozone generating device; and a detection unit that detects an ozone generation parameter in the ozone generating device. The control unit increases temperature of the discharge electrodes up to a vaporizing temperature of dinitrogen pentoxide by controlling the temperature adjustment device and the gas supplying device or the temperature adjustment device and the power source device, based on the output ozone generation parameter, to thereby switch operation from a normal operation mode to a cleaning operation mode in which surfaces of the discharge electrodes and the discharge space are cleaned up while continuing generation of ozone in the discharge space. 110-. (canceled)11. An ozone generating system , comprising:an ozone generating device including discharge electrodes that are arranged opposite to each other to thereby form a discharge space;a gas supplying device that supplies an oxygen-containing gas as a source gas for generating ozone to the discharge space;a power source device that supplies power for discharging to the discharge electrodes;a temperature adjustment device that adjusts a temperature of the discharge electrodes;a control unit that controls the gas supplying device, the power source device and the temperature adjustment device, to thereby control an operation of the ozone generating device; anda detection unit that detects an ozone generation parameter in the ozone generating device;wherein, the control unit causes the temperature of the discharge electrodes to increase up to a vaporizing temperature of dinitrogen pentoxide by controlling the temperature adjustment device and the gas supplying device or the temperature ...

OZONE GENERATOR AND OZONE GENERATION METHOD

In order to generate ozone, which is used for ashing and plasma cleaning, plasma generated in a decompressed chamber is conventionally used. But it is difficult to reduce the production cost of an ozone generation, because facility cost and process cost are expensive in a decompressed process. According to the present invention, ozone is generated by atmospheric pressure plasma CVD using dielectric barrier discharge generated by a plasma head where a plurality of plasma head unit members are installed in parallel to generate plasma by applying electric field or magnetic field via a dielectric member. Stable glow discharge plasma is formed even under atmospheric pressure by dielectric barrier discharge. Then, ozone can be generated under atmospheric pressure, and semiconductor device with low cost can be fabricated. 1. An ozone generator wherein a desired number of flow passage plates are stacked , and each discharge electrode , which is comprised of a ceramic member having a hollow portion and an electrode wire is place without contact with the ceramic member , is placed at the gas outlet side of the each flow passage plate.2. The ozone generator according to claim 1 , characterized in that a gas flow passage is formed along the side of the flow passage plate.3. The ozone generator according to claim 1 , characterized in that the hollow portion is in a vacuum state.4. The ozone generator according to claim 1 , characterized in that gas is enclosed in the hollow portion and the gas is noble gas.5. The ozone generator according to claim 4 , characterized in that the pressure in the hollow portion is reduced to less than or equal to 250 Torr.6. The ozone generator according to claim 4 , characterized in that the noble gas is Ar or Ne.7. The ozone generator according to claim 1 , characterized in that one terminal of the electrode wire was connected to a metal foil claim 1 , the end of the metal foil functions as an external extraction terminal claim 1 , and the metal ...

Ozone Cell Power Supply Apparatus and Method

The present invention generally includes an ozone generation system with a power supply that measures the rate of energy delivered to the ozone generation cell. While changing voltage, frequency or current will likely affect the rate of energy delivery, current, frequency and voltage provide a very poor and unreliable control for an ozone generation cell. It is only through control of the rate of energy delivery that consistent, reliable ozone generation is possible. Based upon the measurements of the rate of energy delivery as measured at the ozone generation cell, compared to the rate of energy delivery supplied, the rate of energy delivery supplied can be adjusted to improve ozone production and control.

Ozone Generation With Directly Cooled Plasma

An ozone generator with a high voltage electrode and at least one counter electrode which limit a gap in which at least one dielectric is arranged and which is flowed through by a gas flow in the direction of flow. The high voltage electrode and the at least one counter electrode are provided with a connection for an electrical power supply to generate silent discharges. A fabric is arranged in the gas flow. The fabric includes a material combination including at least one wire and at least one electrically non-conductive fiber.

SYRINGE DEVICE, SYSTEM AND METHOD FOR DELIVERING OZONE GAS

In accordance with at least one exemplary embodiment, a syringe device, method and system for delivering a therapeutic amount of ozone are disclosed. A sterility case can enclose a syringe portion and can maintain sterility while the syringe device is interfaced to an ozone generator. A valvably-controlled fluid channel can extend from the barrel of the syringe through the case. Conducting elements can be attached to the case and can breach the case. The conductive elements can be connected to electrodes. The electrodes can be attached to the syringe. The syringe portion can be filled with oxygen gas via the valvably-controlled fluid channel. An electric current can be provided to the conductive elements from an ozone generator resulting in a corona discharge from at least one electrode. A therapeutic amount of ozone gas can be produced from the oxygen gas and the syringe delivered into the sterile field without compromise. 1. A syringe device , comprising:a syringe having a plunger slidably engaged with a barrel, the barrel and the plunger cooperating to define a gas chamber; a fluid channel penetrates through the opening of the case when the case operatively encloses the syringe, the fluid channel in fluid communication with the gas chamber;', 'wherein the syringe and case are configured to interface with an ozone conversion unit, and the case maintains sterility of the syringe while interfaced with the ozone conversion unit to effectuate a corona discharge and produce an amount of ozone gas from an amount of oxygen gas within the gas chamber., 'a case for providing substantial sterility, the case including an opening and configured to enclose the syringe;'}2. The syringe device of claim 1 , further comprising:a sterility cap having a portion that is configured to be inserted into the opening of the case and allows for the fluid channel to extend through the sterility cap when the case operatively encloses the syringe.3. The syringe device of claim 1 , further ...

OZONE GENERATOR

An ozone generator includes a transformer, a direct current power supply unit connected to a primary side of the transformer, a reactor connected to a secondary side of the transformer, a semiconductor switch connected between at least one end of a primary winding of the transformer and the direct current power supply unit, and a control circuit for implementing ON-OFF control of the semiconductor switch to thereby apply alternating current voltage to the reactor. The control circuit implements control of a frequency of the alternating current voltage applied to the reactor, so as to minimize electric signal on the primary side of the transformer. 1. An ozone generator comprising:a transformer;a direct current power supply unit connected to a primary side of the transformer;a reactor connected to a secondary side of the transformer;a switching unit connected between at least one end of a primary winding of the transformer and the direct current power supply unit; anda control circuit configured to implement ON-OFF control of the switching unit to thereby apply voltage to the reactor,wherein the control circuit implements control of a frequency of the voltage applied to the reactor so as to minimize electric signal on the primary side of the transformer.2. The ozone generator according to claim 1 , wherein the control circuit implements control to minimize the electric signal on the primary side of the transformer by updating a switching frequency used for ON-OFF control of the switching unit claim 1 , from a reference frequency by a fixed change width.3. The ozone generator according to claim 1 , wherein the switching unit is connected between the one end of the primary winding of the transformer and the direct current power supply unit.4. The ozone generator according to claim 3 , wherein the control circuit implements control of the frequency of the voltage applied to the reactor so as to minimize a current value on the primary side of the transformer.5. The ozone ...

OZONE GENERATOR AND METHOD OF DIAGNOSING FAILURE OF OZONE GENERATOR

An ozone generator includes a transformer, a direct current power supply unit connected to a primary side of the transformer, a reactor connected to a secondary side of the transformer, a semiconductor switch connected between one end of a primary winding of the transformer and the direct current power supply unit, and a control circuit for implementing ON-OFF control of the semiconductor switch to thereby apply alternating current voltage to the reactor. The control circuit implements control to minimize electric signal on the primary side of the transformer by updating a switching frequency by a fixed change width from a reference frequency, and determines that a failure has occurred if the number of updates by the fixed change width exceeds a threshold value. 1. An ozone generator comprising:a transformer;a direct current power supply unit connected to a primary side of the transformer;a reactor connected to a secondary side of the transformer;a switching unit connected between at least one end of a primary winding of the transformer and the direct current power supply unit; anda control circuit configured to implement ON-OFF control of the switching unit using a set switching frequency to thereby apply voltage to the reactor,wherein the control circuit implements control to minimize electric signal on the primary side of the transformer by updating the switching frequency from a reference frequency by a fixed change width, and determines that a failure has occurred if a number of updates by the fixed change width exceeds a threshold value.2. The ozone generator according to claim 1 , wherein at time of resumption of operation of the ozone generator after end of operation of the ozone generator claim 1 , the control circuit starts the control from a frequency set at the end of previous operation claim 1 , instead of the reference frequency; andthe number of updates at the end of the previous operation is used as an initial value, and counting of the number of ...

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.

OZONE GENERATOR WITH HEAT PIPE COOLING

A device for generating ozone from oxygen-containing gas by silent electric discharge, the device including an electrode arrangement having at least one high-voltage electrode and at least one annular ground electrode. An annular dielectric is arranged between the at least one high-voltage electrode and the at least one ground electrode. The at least one high-voltage electrode is surrounded by at least one annular heat pipe. 112-. (canceled)13. A device for generating ozone from oxygen-containing gas , the device comprising:an electrode arrangement comprising:at least one high-voltage electrode;at least one annular ground electrode;an annular dielectric arranged between the at least one high-voltage electrode and the at least one ground electrode, andone or more annular heat pipes surrounding the at least one high-voltage electrode, each annular heat pipe comprising an annular space in cross section defined by an outer wall radially spaced from an inner wall.14. The device of claim 13 , wherein one or more of the at least one high-voltage electrode claim 13 , the at least one ground electrode claim 13 , and the annular dielectric comprise the one or more annular heat pipes.15. The device of claim 14 , wherein the at least one high-voltage electrode includes a central high-voltage electrode claim 14 , the high-voltage electrode comprising a metal heat pipe having a circular cross-section and defining an enclosed cavity.16. The device of claim 15 , wherein the metal heat pipe comprises a closed heat exchange system.17. The device of claim 15 , wherein each of the metal heat pipe and the one or more annular heat pipes comprises a closed heat exchange system.18. The device of claim 14 , wherein the at least one high-voltage electrode includes a central high-voltage electrode comprising a filler material arranged on a heat pipe claim 14 , the heat pipe having a circular cross-section and defining an enclosed cavity.19. The device of claim 18 , wherein the heat pipe ...

Environmental sanitizer and odor remover for purification of foods, surfaces, air and water with disposable ozone generation electrode, pressure/flow adaptable venturi injector and aqueous phase filter device

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.

CORONA EFFECT PLASMA DEVICE AND PLASMA REACTOR

A corona plasma cell includes a polarized electrode and a ground electrode, including a cylinder and a porous film, with the cylinder having a low profile and the polarized electrode not entering the cylinder; a corona plasma dual element including a first cell, a second cell having such a structure, which first and second cell are symmetrically arranged; and finally a plasma reactor including a plurality of cells or dual elements. 11112131214121512141214. A corona plasma cell () comprising a substantially needle-shaped polarized electrode () and a ground electrode () , arranged opposite the polarized electrode () , comprising a cylinder () substantially centered on the polarized electrode () , and a porous film () substantially plane perpendicular to the polarized electrode () , wherein the cylinder () has a low profile , and the polarized electrode () does not enter the cylinder ().211151214. The cell () of claim 1 , wherein the porous film () is arranged claim 1 , relative to the polarized electrode () claim 1 , on the side opposite the cylinder ().31011121312212223221121. A corona plasma dual element () comprising a first corona plasma cell () as defined in claim 1 , comprising a first polarized electrode () and a first ground electrode () claim 1 , arranged opposite the first polarized electrode () claim 1 , a second corona plasma cell () as defined in claim 1 , comprising a second polarized electrode () and a second ground electrode () claim 1 , arranged opposite the second polarized electrode () claim 1 , wherein the first cell () and the second cell () are arranged symmetrically.41012228132398. The dual element () of claim 3 , wherein the first polarized electrode () and the second polarized electrode () are connected to a same first potential () claim 3 , and the first ground electrode () and the second ground electrode () are connected to a same second potential () claim 3 , different from the first potential ().51089. The dual element () of claim 4 , ...

METHOD FOR CONTROLLING AN OZONE GENERATOR

A method for controlling an ozone generator with a high-voltage electrode, at least one counter electrode, and a gap in which at least one dielectric is arranged and which is perfused by an oxygen-containing gas having a particle density n. The high-voltage electrode and the at least one counter electrode are provided with a connection for an electrical voltage supply for generating silent discharges in at least one discharge gap. Striking distances d of the discharge are distributed between a minimum striking distance dand a maximum striking distance d. For the generation of an ozone concentration>12 wt. % ozone, the voltage amplitude Uof an AC voltage on the electrical voltage supply is selected so that U<130*10V*m*n*d*(C+C)/C, with C=capacitance of the dielectric and C=capacitance of the discharge gap. 112.-. (canceled)13. A method for controlling an ozone generator with a high-voltage electrode and at least one counter electrode , wherein the high-voltage electrode and the at least one counter electrode delimit a gap in which at least one dielectric is arranged and which is perfused by an oxygen-containing gas having a particle density n , and wherein the high-voltage electrode and the at least one counter electrode include a connection for an electrical voltage supply for generating silent discharges in at least one discharge gap , and wherein striking distances d of the discharge are distributed between a minimum striking distance dand a maximum striking distance d , said method comprising:{'sub': 0', '0', 'gas', 'max', 'DL', 'g', 'DL', 'gas', 'max', 'DL', 'g, 'sup': −21', '2, 'generating an ozone concentration having greater than 12 wt. % ozone using a voltage amplitude Uof an AC voltage on the electrical voltage supply such that U<130*10V* m*n*d*(C+C)/C, with the particle density n, the largest striking distance d, the capacity of the dielectric Cand the capacity of the discharge gap C.'}14. The method according to claim 13 , wherein U<120*10V*m*n*d*(C+C)/C. ...

Ozone Generator, System, and Methods for Retrofit of Enclosed and Air-Conditioned Environments

An ozone generator includes at least four independent ozone generation control channels that energize at least four independent ozone generation plates. The at least four independent ozone generation control channels allow for multiple modes of operation, including sterilization, disinfecting, and managing, in addition to interleaved operation, which significantly extends the useful life of the individual ozone generation plates. The ozone generator is placed in a preexisting conditioned airflow that enters a conditioned airspace enclosed by a container. Being placed in the preexisting conditioned airflow, the ozone generator does not require a fan or other air movement device to actively transport ozone-enriched air or oxygen through the ozone generator. 1. A conditioned airflow ozone generator for generating ozone in an enclosed airspace , the ozone generator comprising: where the back and the front are substantially planar, the top and the bottom are substantially planar, and the left and right sides are substantially planar,', 'where from 10% to 70% of the surface area of the back includes perforations allowing passage of the previously existing airflow,', 'where from 10% to 70% of the surface area of the front includes perforations allowing passage of the previously existing airflow,', 'where from 30% to 95% of the surface area of the bottom includes perforations allowing passage of the previously existing airflow;', 'a right attachment side extending between the back and the front of the enclosure;', 'a right attachment member attached to the right attachment side, the right attachment member configured to attach the right attachment side to the interior of an enclosed airspace including a previously existing conditioned airflow;', 'a left attachment side extending between the back and the front of the enclosure;', 'a left attachment member attached to the left attachment side, the left attachment member configured to attach the left attachment side to the ...

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 ...

APPARATUS AND METHODS FOR ELECTRONIC MONITORING OF OZONE GENERATORS

Apparatus and methods for electronic monitoring of ozone generators are provided herein. In certain configurations, an ozone generator includes ozone generation circuitry for producing ozone and a control circuit that monitors the ozone generation circuitry to determine whether or not ozone is being properly produced. The control circuit includes an AC input that receives power from an AC power supply and one or more AC outputs for providing AC output voltages to the ozone generation circuitry. The control circuit further includes one or more AC current sensors used to monitor a status of ozone production by monitoring AC current flowing into the ozone generation circuitry via the control circuit's AC outputs. The control circuit alerts a user of the status of ozone production while avoiding a need for the user to test a treatment fluid for ozone concentration and/or manually inspect or test components of the ozone generator. 1. An ozone generator comprising:ozone generation circuitry; anda control circuit comprising an AC input configured to receive an AC input voltage and one or more AC outputs configured to provide one or more AC output voltages to the ozone generation circuitry,wherein the control circuit further comprises a first AC current sensor configured to sense an AC current flowing from a first AC output of the one or more AC outputs into the ozone generation circuitry.2. The ozone generator of claim 1 , wherein the ozone generation circuitry comprises a first generator plate claim 1 , wherein the first AC current sensor is configured to detect when the first generator plate is producing ozone.3. The ozone generator of claim 1 , wherein the control circuit is configured to generate at least one a visual indication claim 1 , an audio indication claim 1 , or an electronic notification based on the sensed AC current.4. The ozone generator of claim 1 , wherein the control circuit further comprises a second AC current sensor configured to sense an AC current ...

OZONE GENERATOR

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. 1: An ozone generator comprising:a container into which a material gas is caused to flow;a first metal electrode that is a cylindrical electrode the axial direction of which is a first direction, being disposed in the container, and has an outer peripheral surface to which a cooling medium is supplied;a cylindrical dielectric 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;a heat pipe having electrical conductivity that is disposed to be opposed to an inner peripheral surface of the dielectric electrode;a heat sink that 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; anda power supply unit that applies voltage to the heat pipe to cause electric discharge in the material gas in at least one of a first gap and a second gap to generate ozone by the electric discharge, the first gap being a gap into which the material gas is caused to flow between the first metal electrode and the dielectric electrode, the second gap being a gap into which the material gas is caused to flow ...

OZONE GENERATING MACHINE FOR USE IN A SHIP

Ozone generating machine for generating ozone in a ship, comprising: 2. Ozone generating machine (OGM) according to the preceding claim , wherein a perpendicular projection on the base (B) of said at least one pair of cross-brace beams (CB) is comprised within a perpendicular projection on the base (B) of the ozone generator (OG).3. Ozone generating machine (OGM) according to any one of the preceding claims , wherein the frame comprises at least one top reinforcing plate (TRE) attached to a top portion of a pillar (P) and to the top subframe (TSF) , and/or at least one bottom reinforcing plate (BRE) attached to a bottom portion of a pillar (P) and to the base (B).4. Ozone generating machine (OGM) according to the preceding claim , wherein said at least one top reinforcing plate (TRE) is attached to a top portion of a pillar (P) with two attachment points and to the top subframe (TSF) with two attachment points , and/or at least one bottom reinforcing plate (BRE) is attached to a bottom portion of a pillar (P) with two attachment points and to the base (B) with two attachment points.5. Ozone generating machine (OGM) according to any one of the or , wherein each beam of the cross-brace beams (CB) is attached to the top portion of a pillar (P) via a top reinforcing plate (TRE) and to the bottom portion of another pillar (P) via a bottom reinforcing plate (BRE).6. Ozone generating machine (OGM) according to any one of the preceding claims , wherein the ozone generator (OG) presents an axial length defining an axial direction , the axial direction being parallel to a base (B) plane defined by the base (B) , and wherein an axial length of each beam of said at least one pair of cross-brace beams (CB) is parallel to a longitudinal plane being parallel to the axial direction and perpendicular to the base (B) plane.7. Ozone generating machine (OGM) according to the preceding claim , comprising two pairs of pillars (P) , each pair of pillars (P) being equipped with one pair of ...

DISCHARGE GENERATOR

In a discharge generator, a control unit switchably performs a continuous mode and a burst mode based on determination of whether target output power is higher than discharge start power. The burst mode alternately performs a discharge mode and a non-discharge mode. The control unit causes a burst ratio to be set to a value expressed by the following equation b=P*/Pwhere b represents the burst ratio, P* represents the target output power, and Prepresents the discharge start power. The burst ratio is defined as a ratio of the discharge period to a burst period. The burst period is the sum of the discharge period and the stop period. The control unit causes, in the burst mode, the switch circuit to output, as the output power, the discharge start power during the discharge period. 1. A discharge generator comprising:a switch circuit comprising a switch connected to a direct-current power source; anda control unit configured to control on-off switching operations of the switch to thereby convert direct-current power supplied from the direct-current power source to the switch circuit into alternating-current output power, thus causing a discharge load to generate discharge based on the output power, switchably perform a continuous mode and a burst mode in accordance with determination of whether target output power as a target value of the output power is higher than predetermined discharge start power,', 'the continuous mode continuously performing on-off switching operations of the switch,', a discharge mode that performs on-off switching operations of the switch to thereby cause the discharge load to generate discharge during a discharge period; and', 'a non-discharge mode that performs no switching operations of the switch, to thereby prevent the discharge load from generating discharge during a stop period,, 'the burst mode alternately performing, 'the discharge start power being minimum power required for the discharge load to generate discharge; and', 'control, ...

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 ...

ENVIRONMENTAL SANITIZER AND ODOR REMOVER FOR PURIFICATION OF FOODS, SURFACES, AIR AND WATER WITH DISPOSABLE OZONE GENERATION ELECTRODE, PRESSURE/FLOW ADAPTABLE VENTURI INJECTOR AND AQUEOUS PHASE FILTER DEVICE

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. 131.-. (canceled)32. A kit comprising: a water entry port at a first distal end of the venturi injector into which an end of a water input tube is insertable,', 'a water exit port at a second distal end of the venturi injector opposed to said water entry port, and into which a water exit tube is insertable, and', 'a gas entry port disposed transverse to the water entry port and the water exit port into which a gas transport tube is insertable,', 'wherein the venturi injector is configured such that, when water flows between the water entry port and the water exit port through a central tube, the water provides a motive force creating suction at the gas intake port, which draws in gas through the gas intake port and dissolves the gas in the water flow; and, 'a venturi injector for mixing a gas with water, the venturi injector comprisinga plurality of removable motive throat inserts, each being configured to be removably located within the water entry port, the plurality of removable motive throat inserts being configured for use with different water flows or ...

OZONE GENERATING SYSTEM AND OPERATION METHOD THEREOF

In an ozone generating system which performs intermittent operation, that is, an operation in an ozone generating operation period in which ozone is generated by discharging gas including oxygen at a discharge electrode part and an operation in an ozone generating operation standby period in which ozone is not generated by stopping discharge are alternately repeated, a gas circulating device which circulates gas in the ozone generating apparatus and removes at least nitric acid from the gas which is circulated is connected to the ozone generating apparatus. 1. An ozone generating system comprising:an ozone generating apparatus having discharge electrodes which are arranged facing each other so as to form discharge space,a gas supplying device supplying a material gas including oxygen to the ozone generating apparatus,a cooling device supplying cooling water for cooling the discharge electrodes,a power supply supplying electricity to the discharge electrodes for discharging anda control unit controlling the gas supplying device and the power supply,wherein the control unit controls so as to perform an intermittent operation, in which an ozone generating operation period in which ozone is generated by the ozone generating apparatus by supplying a material gas from the gas supplying device to the ozone generating apparatus and by supplying of electricity from the power supply to the discharge electrodes and an ozone generating operation standby period in which supplying of gas from the gas supplying device to the ozone generating apparatus and supplying of electricity from the power supply to the discharge electrodes is stopped are alternately repeated,wherein a gas refining unit removing at least nitric acid which is contained in gas is provided, andthe control unit controls such that in the ozone generating operation standby period, the gas in the ozone generating apparatus is replaced by the material gas, and the pressure in the ozone generating apparatus is ...

Ozone generator with position-dependent discharge distribution

An ozone generator includes a high-voltage electrode and at least one counter electrode, which define an interstice in which at least one dielectric is arranged and through which a gas flows in the flow direction, the high-voltage electrode and the at least one counter electrode being provided with a connection for an electrical voltage supply to generate silent discharges, and a wire fabric being arranged in the gas flow and its density decreasing in the flow direction.

OZONE GENERATION DEVICE AND FUSE HOLDER

According to one embodiment, an ozone generation device includes a first electrode unit, a second electrode unit, a fuse and a fuse holder. The first electrode unit is provided on an inner face of a discharge tube. The second electrode unit is provided outside the discharge tube at an interval. The second electrode faces the first electrode unit. A diameter of the outer face of the fuse is smaller than a diameter of the inner face. At least a part of the outer face is positioned inside the discharge tube. The fuse holder is interposed between the discharge tube and the fuse, includes the outer periphery and an inner periphery and is provided with a first opening and a second opening. The outer periphery extends in an arc along the inner face to come into contact with the inner face. The inner periphery extends in an arc along the outer face to come into contact with the outer face. 1. An ozone generation device , comprising:a first electrode unit provided on an inner face of a discharge tube having a cylindrical shape;a second electrode unit provided outside the discharge tube at an interval, the second electrode facing the first electrode unit;a fuse comprising an outer face, a diameter of the outer face is smaller than a diameter of the inner face, the fuse having a cylindrical shape, at least a part of the outer face being positioned inside the discharge tube; anda fuse holder having a C shape as well as a plate shape substantially, the fuse holder being interposed between the discharge tube and the fuse, the fuse holder comprising the outer periphery and an inner periphery and being provided with a first opening and a second opening, the outer periphery extending in an arc along the inner face to come into contact with the inner face, the inner periphery extending in an arc along the outer face to come into contact with the outer face, the first opening being positioned on a side of an axial center of the inner periphery to receive the fuse, the second opening ...

Piezoelectric Transformer

In an embodiment a method includes applying an AC voltage to an input region, converting, by the input region, the AC voltage into a mechanical oscillation, converting, by an output region, the mechanical oscillation into an electrical voltage and igniting a plasma at an output-side end side of an piezoelectric transformer, wherein the piezoelectric transformer includes the input region and the output region, wherein the piezoelectric transformer includes a longest edge and a shortest edge, and wherein the longest edge has a length that is twenty times a length of the shortest edge or less. 1. A method for generating a plasma using a piezoelectric transformer , the method comprising:applying an AC voltage to an input region;converting, by the input region, the AC voltage into a mechanical oscillation;converting, by an output region, the mechanical oscillation into an electrical voltage; andigniting the plasma at an output-side end side of the piezoelectric transformer,wherein the piezoelectric transformer comprises the input region and the output region,wherein the piezoelectric transformer comprises a longest edge and a shortest edge, andwherein the longest edge comprises a length that is twenty times a length of the shortest edge or less.2. The method according to claim 1 , wherein the longest edge comprises the length of less than 45 mm.3. The method according to claim 1 , wherein the longest edge comprises the length of less than 35 mm.4. The method according to claim 1 ,wherein a first external electrode is arranged on a first side surface of the input region,wherein a second external electrode is arranged on a second side surface of the input region, the second side surface arranged opposite the first side surface,wherein the input region comprises piezoelectric layers and electrodes stacked one above another in a stacking direction,wherein the electrodes are contacted either with the first external electrode or with the second external electrode alternately ...

Ozone generator

Ozone generator cells that include two thermally conductive plates that maintain contact between various layers of the cells in the absence of a bonding agent. The cells lack aluminum-containing materials in the discharge region of the cell.

Ozone generator

The present invention has as its object the provision of an ozone generator that can generate ozone with high efficiency. The ozone generator of the present invention includes: source gas supply means for supplying a source gas containing oxygen; a gas flow channel forming member for forming a gas flow channel through which the source gas from the source gas supply means flows; and an ultraviolet light source for emitting ultraviolet light, the ultraviolet light source being disposed in the gas flow channel. The ozone generator irradiates the source gas flowing through the gas flow channel with the ultraviolet light from the ultraviolet light source to cause the oxygen in the source gas to absorb the ultraviolet light and thereby generate ozone. The ultraviolet light source comprises an excimer lamp for emitting ultraviolet light with a wavelength of not more than 200 nm. A flow rate of the source gas in a region where the ultraviolet light source is disposed in the gas flow channel is not lower than 0.1 m/s.

Tube-type ozone generator and manufacturing method therefor

A tube-type ozone generator 1 including an ozone generation unit 30 A is provided. The ozone generation unit 30 A includes an outer electrode tube 31 and an inner electrode tube 32 provided inside the outer electrode tube with a discharge gap 36 interposed between the outer and inner electrode tubes 31 and 32 . The inner electrode tube 32 has a dielectric tube 33 and a cylindrical electrode 34 being in close contact with an inner circumferential surface of the dielectric tube 33 . The electrode 34 is removably disposed inside the dielectric tube 33.

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 Подробнее

OZONE GENERATOR OF A GAS BLOW-THROUGH TYPE, ESPECIALLY TO PRODUCE A GAS MIXTURE OF OZONE/AIR OR OZONE/OXYGEN

An ozone generator of a gas blow-through type, especially to produce a gas mixture of ozone/air or ozone/oxygen. An ozone producing structural unit in the path of the blown air or oxygen is used as ozone source. The ozone producing structural unit is operated on the principle of alternating current auxiliary electrode cold arc discharge with its capacity increased by limited arc discharge, with an alternating voltage voltage source. This solution does not result in high-temperature arc discharges, thus the fire hazard may be eliminated, and at the same time the device is capable of producing extremely large quantities of ozone. The ozone producing structural unit of the ozone generator is placed in one or more insulating housings/air ducts, placed in a direction parallel to or coaxial to the air blowing direction. Further details of the apparatus are disclosed herein. 11213124511067898. An ozone generator of a gas blow-through type , especially to produce a gas mixture of ozone/air or ozone/oxygen , said generator comprises electrode groups comprising two flat electrode plates () , one dielectric plate () disposed between the flat electrode plates () , insulating shim plates () arranged between each of flat electrode plates () and the dielectric plate () , as well as insulating spacer frame elements () and electrode studs () arranged on the flat electrode plates () , said electrode studs being electrically connected to a high voltage high frequency electric generator unit () of the ozone generator through a first high voltage cable () and a second high voltage cable () characterized by an outer insulating housing () , held together and fastened by suitable fastening screws () , wherein the outer insulating housing () is dimensioned so as to allow several electrode groups to be modularly arranged within said housing parallel to each other side by side and to be electrically connected.2112. The ozone generator according to claim 1 , characterized in that the at least ...

FLEXIBLE PLASMA APPLICATORS BASED ON FIBROUS LAYERS

Disclosed herein are flexible plasma applicators based on fibrous layers that are capable of rapidly sanitizing a surface via either direct or indirect contact with said surface. 1. A plasma applicator consisting of: wherein the first substrate layer and the second substrate layer are comprised of a fibrous base layer and a metallic surface layer,', 'wherein the adhesive layer binds the fibrous base layer of the first substrate layer to the fibrous base layer of the second substrate layer, and', 'wherein the metallic surface layer of the first substrate layer and the metallic surface layer of the second substrate are exposed and configured to be placed in conductive contact with a high voltage source to generate dielectric barrier discharge (DBD)-based plasma comprising at least one of volume plasma and surface plasma upon exposure to the high voltage source., 'a first substrate layer, a second substrate layer, and an adhesive layer,'}2. The plasma applicator of claim 1 , wherein the DBD-based plasma is configured to kill or inhibit growth of a microorganism or a virus on a surface or on an object.3. The plasma applicator of claim 1 , wherein the high voltage source is configured to apply an alternating current (AC) input with a frequency of about 1 kHz to about 10 kHz to the plasma applicator and a peak-to-peak voltage (Vp-p) ranging from about ±0.5 kV to about ±5 kV.4. The plasma applicator of claim 3 , wherein the AC input has a voltage of about 1 kV to about 100 kV.5. The plasma applicator of claim 1 , wherein the DBD-based plasma is configured to generate ozone.6. The plasma applicator of claim 1 , wherein the first substrate layer comprises a plurality of hexagon-shaped apertures forming a honeycomb pattern.7. A bandage for promoting wound healing claim 1 , comprising the plasma applicator of and a non-conductive spacer attached on a surface of the plasma applicator claim 1 , the non-conductive spacer being adapted to be placed on skin tissue.8. A device for ...

METHOD OF REMEDIATING SUB-SLAB VAPORS AND SOILS OF BUILDINGS AND SYSTEM THEREOF

A method is provided for treating contaminants in the vapors and shallow soils in an area below a slab of a building such that the slab is located above a first layer of gravel and a second layer of soil. The method includes providing an ozone unit, a riser pipe, and tubing. An area below the slab where contaminants need treated is first detected and then a hole is formed in the slab to define an injection location. The method also includes positioning the riser pipe in the hole at the injection location and coupling the tubing between the ozone unit and the riser pipe. The method further includes dispensing ozone from the ozone unit to flow through the tubing and the riser pipe to treat contaminants in the vapors and shallow soils in the area below the slab. 1. A remediation system for performing a remediation process for treating contaminants located in an area below a slab of a building , comprising:an ozone unit for generating a supply of ozone;a plurality of injection locations defined in the sub-slab area, where each of the plurality of injection locations is spaced from another of the plurality of injection locations by a predefined distance;a riser pipe positioned at each of the plurality of injections locations, the riser pipe having a defined length configured to extend from a top surface of the slab to a location below the slab, where the riser pipe comprises an outlet at the location below the slab; anda tubing coupled between the ozone unit and the riser pipe;wherein, during the remediation process, the ozone unit is disposed in its enabled position to dispense ozone through the tubing and the riser pipe;further wherein, the ozone exits the outlet of the riser pipe at each of the plurality of injection zones and disperses in the area below the slab to treat contaminants located thereabout.2. The remediation system of claim 1 , further comprising a plurality of application zones defined at each of the injection zones by an area of dispersion of the ozone ...

OZONE GENERATION APPARATUS

In an ozone generation apparatus, a discharge cell includes a first electrode part, a second electrode part, and a dielectric partition plate. The first electrode part and the second electrode part face each other, and the dielectric partition plate is provided between the first and second electrode parts.

OZONE GENERATION SYSTEM AND METHOD FOR OPERATING SAME

In an ozone generating system in which an intermittent operation is performed, in which an ozone generating operation period in which ozone is generated by discharging gas which contains oxygen in a discharge space of an ozone generating apparatus and an ozone generating operation standby period in which gas is sealed in an ozone generating apparatus and discharge is stopped so as not to generate ozone are performed repeatedly, an absorbent which absorbs at least one of nitric acid and nitrogen oxide is provided in an ozone generating apparatus other than the discharge space. 1. An ozone generating system comprisingan ozone generating apparatus having discharge electrodes which are arranged facing each other so as to form a discharge space,a gas supplying device for supplying a material gas including oxygen to the ozone generating apparatus,a cooling device supplying cooling water for cooling the discharge electrodes,a power supply supplying electricity to the discharge electrodes for discharging anda control unit controlling the gas supplying device and the power supply,wherein the control unit controls so as to perform an intermittent operation, in which an ozone generating operation period in which ozone is generated by the ozone generating apparatus by supplying a material gas from the gas supplying device to the ozone generating apparatus and by supplying of electricity from the power supply and an ozone generating operation standby period in which supplying of gas from the gas supplying device to the ozone generating apparatus and supplying of electricity from the power supply to the discharge electrodes is stopped are alternately repeated, wherein the control unit controls to seal the material gas in the ozone generating apparatus in the ozone generating operation standby period, and an absorbent which absorbs at least one of nitric acid and nitrogen oxide is provided at a position which is in the ozone generating apparatus other than the discharge space and ...

OZONE GENERATOR AND INTERNAL COMBUSTION ENGINE WITH OZONE GENERATOR

An ozone generator and an internal combustion engine with the ozone generator that can raise ozone additive rate of whole intake air, while suppressing pressure loss in the intake pipe from increasing. The internal combustion engine with an ozone generator includes a tubular intake pipe, through an inner region of which air flows, an ozone generator having an electrode plate that makes ozone and is disposed in the inner region or in the intake pipe, and a limiter that limits the flow of air in the inner region of the intake pipe; the electrode plate has a planar dielectric and high-voltage-side and low-voltage-side electrodes adhered and fixed to the dielectric and is formed in a shape of a plate extending in a direction in which air flows. 116-. (canceled)17. An internal combustion engine with an ozone generator , comprising:a tubular intake pipe, through an inner region of which air to be taken into a cylinder flows;the ozone generator including an electrode plate that makes ozone produced and is disposed in the inner region or in the intake pipe; anda limiter that limits the flow of the air in the inner region,wherein the electrode plate has a planar dielectric and high-voltage-side and low-voltage-side electrodes adhered and fixed to the dielectric and formed in a shape of a plate extending in a direction in which the air flows,wherein the air inlet and the air outlet of the portion of the intake pipe, in which the electrode plate and the limiter are arranged, face each other, andwherein the limiter is a body separate from the tubular intake pipe, disposed in the inner region to be spaced apart by a gap from each of the intake pipe and the electrode plate, and extends in a direction from the air inlet to the air outlet, an end portion thereof facing the air inlet limits the flow of the air.18. The internal combustion engine with the ozone generator according to claim 17 ,wherein the limiter includes a columnar member formed in a shape of a column extending in ...

COLD PLASMA OZONE GENERATOR

The present invention provides a cold plasma ozone generator, comprising: an inlet gas port; at least one in-electrode, said in-electrode having a plurality of holes substantially at a perimeter of the same; said plurality of perimeter holes are in fluid communication with said inlet gas port, said plurality of perimeter holes configured to allow said dry gas to pass therethrough; at least one out-electrode, said out-electrode having at least one hole at the center of the same, said at least one hole configured to allow gas to pass therethrough; said in-electrode and said out-electrode configured to maintain said high voltage AC therebetween; at least one spacer between said in-electrode and said out-electrode, said spacer configured to maintain a constant-width gap between said in-electrode and said out-electrode; an outlet port. 1. A cold plasma ozone generator to generate ozone from oxygen in a gas , said cold plasma ozone generator comprising:an inlet gas port;at least one in-electrode, said in-electrode having a plurality of holes substantially at a perimeter of the in-electrode; said plurality of perimeter holes are in fluid communication with said inlet gas port, said plurality of perimeter holes configured to allow gas to pass therethrough;at least one out-electrode, said out-electrode having at least one hole at the center of the out-electrode, said at least one hole configured to allow gas to pass therethrough;said in-electrode and said out-electrode configured to maintain high voltage AC therebetween;at least one spacer between said in-electrode and said out-electrode, said spacer configured to maintain a constant-width gap between said in-electrode and said out-electrode, said constant-width gap configured to allow said gas to pass from said plurality of perimeter holes in said in-electrode to said at least one hole in said out-electrode; andan outlet port in fluid communication with said at least one hole in said out-electrode.2. The cold plasma ozone ...

Ozone Generation System

An ozone generation system which is adaptable for supplying ozone to different medium and small application processes. The system has a source of feed gas, a corona discharge cell receiving the feed gas from the feed gas source and generating ozone for the application process, a flow controller measuring and managing the flow of the feed gas from the feed gas source to the corona discharge cell; and a regulator receiving gas from the corona discharge cell and sending the gas to the application process. The regulator maintains pressure in the corona discharge cell independent of the application process pressure.

OZONE GENERATOR VOLTAGE VERIFICATION LIGHT ASSEMBLY

An ozone generator voltage verification light assembly generates a visual or audible indicator, such as a neon light, to verify that an ozone generator is generating the proper voltage to generate ozone, and/or ozone generator voltage verification light assembly testing assembly operatively connects to an ozone generator, and visually indicates if an irregularity in voltage occurs. The ozone generator includes a power source for supplying electrical current, and a transformer that generates high voltage. The ozone generator also includes single or multiple ceramic plates disposed in a spaced-apart, parallel relationship, and coated with stainless steel mesh. Voltage generated by the transformer contacts the ceramic plates by means of an electrode. Accordingly, ozone is generated by discharging electricity through electrodes that contact in both sides of ceramic plate. 1. An ozone generator voltage verification light assembly , the assembly comprising: a power source supplying an electrical current;', 'a transformer generating high voltage by boosting voltage supplied from the power source;', 'at least one ceramic plate disposed in a spaced-apart, parallel relationship;', 'a metal housing encapsulating the ceramic plate; and', 'whereby, when the ozone generator is operational to generate ozone, a predetermined voltage is generated by the transformer, the predetermined voltage contacting both sides of the ozone plate via an electrode., 'an ozone generator operable to produce ozone, the ozone generator having2. The assembly of claim 1 , wherein the assembly operatively connects to the metal case and the electrode that supplies power to the ceramic plate claim 1 , the assembly detects the voltage passing to the ceramic plate claim 1 , the assembly generates an alert signal by turning off if the detected voltage exceeds a range of the predetermined voltage.3. The assembly of claim 1 , further comprising a metal housing and a handle.4. The assembly of claim 3 , wherein ...

PLASMA OZONE GENERATOR

A plasma ozone generator includes a discharge unit assembly, a high-voltage electrode bar assembly, an oxygen pipeline assembly, an ozone pipeline assembly, a cooling water inlet pipeline assembly, and a cooling water return pipeline assembly. By using the plasma ozone generator of the present disclosure, performance indicators such as a small volume, a high yield, small concentration decay, low power consumption, easy maintenance, and modularization are achieved, and an explosion-proof function and a flame-retardant function are generally provided, thereby achieving a safer and more reliable effect. 1. A plasma ozone generator , comprising:a discharge unit assembly,a high-voltage electrode bar assembly,an oxygen pipeline assembly,an ozone pipeline assembly,a cooling water inlet pipeline assembly, anda cooling water return pipeline assembly,wherein the discharge unit assembly is configured to produce a corona discharge;wherein the high-voltage electrode bar assembly is connected to the discharge unit assembly and is configured to feed a high-voltage current;wherein the oxygen pipeline assembly is connected to an inlet of the discharge unit assembly and is configured to feed oxygen;wherein the ozone pipeline assembly is connected to an outlet of the discharge unit assembly and is configured to emit ozone; andwherein the cooling water inlet pipeline assembly, a cooling water channel in the discharge unit assembly, and the cooling water return pipeline assembly are connected in sequence, to cool the discharge unit assembly.2. The plasma ozone generator of claim 1 , further comprising:a front generator support assembly; anda rear generator support assembly,wherein the front generator support assembly and the rear generator support assembly are used to fix the discharge unit assembly, the high-voltage electrode bar assembly, the oxygen pipeline assembly, the ozone pipeline assembly, the cooling water inlet pipeline assembly, and the cooling water return pipeline assembly ...

OZONE GENERATING ASSEMBLY AND OZONE GENERATOR

Provided is an ozone generating assembly, including a conductive pillar, an insulating sleeve sleeved on an outer periphery of the conductive pillar, a conductive sleeve sleeved on an outer periphery of the insulating sleeve, and insulating brackets arranged at two ends of the conductive pillar and used to arrange an inner wall of the conductive sleeve and an outer wall of the conductive pillar in parallel and at an interval. Air guiding holes are uniformly distributed on an outer peripheral surface of the conductive sleeve, and an ozone channel is formed by the air guiding holes and a gap between the inner wall of the conductive sleeve and an outer wall of the insulating sleeve. Further provided is an ozone generator, which is low in energy consumption, good in heat dissipation effect, and high in ozone release efficiency. 1. An ozone generating assembly , comprising:a conductive pillar;an insulating sleeve sleeved on an outer periphery of the conductive pillar;a conductive sleeve sleeved on an outer periphery of the insulating sleeve; andinsulating brackets arranged at two ends of the conductive pillar and used to arrange an inner wall of the conductive sleeve and an outer wall of the conductive pillar in parallel and at an interval;wherein air guiding holes are uniformly distributed on an outer peripheral surface of the conductive sleeve, and an ozone channel is formed by the air guiding holes and a gap between the inner wall of the conductive sleeve and an outer wall of the insulating sleeve.2. The ozone generating assembly according to claim 1 , wherein each of the air guiding holes is a circular hole claim 1 , a waist shaped hole claim 1 , or an oval hole.3. The ozone generating assembly according to claim 1 , wherein a fist electrode is arranged at one end of the conductive pillar claim 1 , and a second electrode is welded to the outer peripheral surface of the conductive sleeve.4. The ozone generating assembly according to claim 1 , wherein a ring shaped ...

Ozone Generator Methods for Retrofit of Enclosed and Air-Conditioned Environments

An ozone generator includes at least four independent ozone generation control channels that energize at least four independent ozone generation plates. The at least four independent ozone generation control channels allow for multiple modes of operation, including sterilization, disinfecting, and managing, in addition to interleaved operation, which significantly extends the useful life of the individual ozone generation plates. The ozone generator is placed in a preexisting conditioned airflow that enters a conditioned airspace enclosed by a container. Being placed in the preexisting conditioned airflow, the ozone generator does not require a fan or other air movement device to actively transport ozone-enriched air or oxygen through the ozone generator. 1. A method of operating a conditioned airflow ozone generator in an enclosed airspace in a previously existing conditioned airflow to extend produce and other foods shelf-life after shipment , the method comprising:sterilizing an enclosed airspace lacking produce and other foods with a conditioned airflow ozone generator placed in a previously existing conditioned airflow within the enclosed airspace, where the enclosed airspace maintains from 4 to 8 ppm ozone for a time period from 10 to 20 minutes;disinfecting produce and other foods within the enclosed airspace with the conditioned airflow ozone generator placed in the previously existing conditioned airflow, where the enclosed airspace maintains from 2 to 3.9 ppm ozone for a time period from 15 minutes to 2 hours; andmanaging the produce and other foods within the enclosed airspace with the conditioned airflow ozone generator during transport of the produce and other foods, where the enclosed airspace maintains from 0.5 to 1.5 ppm ozone for a time period after termination of the disinfecting.2. The method of claim 1 , where the sterilizing the enclosed airspace includes operating at least four ozone generation control channels to energize at least four ozone ...

Ozone Cell Power Supply Apparatus and Method

The present invention generally includes an ozone generation system with a power supply that measures the rate of energy delivered to the ozone generation cell. While changing voltage, frequency or current will likely affect the rate of energy delivery, current, frequency and voltage provide a very poor and unreliable control for an ozone generation cell. It is only through control of the rate of energy delivery that consistent, reliable ozone generation is possible. Based upon the measurements of the rate of energy delivery as measured at the ozone generation cell, compared to the rate of energy delivery supplied, the rate of energy delivery supplied can be adjusted to improve ozone production and control. 1. A method of generating ozone , comprising:delivering power to an ozone generating cell;measuring the rate of energy delivery applied to the ozone generating cell; andadjusting a parameter of the output applied to the ozone generation cell.2. The method of claim 1 , wherein the measuring comprises developing an analog of power supplied to one or more switching elements.3. The method of claim 2 , wherein the measuring comprises feeding the measurement of power to a window comparator and delivering a pulse to an adder unit through a multi-vibrator.4. The method of claim 1 , further comprising changing the frequency of the power in response to the measuring.5. For an ozone generation system having an ozone generation cell claim 1 , a transformer having a high voltage output connected to the ozone generation cell for powering the ozone generation cell claim 1 , and a power supply subsystem connected to an input of the transformer claim 1 , the ozone generation system having a resonant frequency during operation claim 1 , a method of operation comprising:driving current and voltage through the transformer and ozone generation cell at a driving frequency to control power delivered by the power supply subsystem to the ozone generation cell by the driving frequency; ...

AIR PURIFIER

An air purifier () includes a housing () formed with an air duct (), an ozone generation device (), an activated carbon purification unit (), and a fan () arranged in the air duct (). The air duct () includes an air inlet () and an air outlet (). The air outlet () is disposed indoors. The ozone generation device () and the activated carbon purification unit () are arranged in the air duct () along the direction of the air inlet to the air outlet (), and the ozone generation device () is used to generate ozone. The fan () is used to suck gas from the air inlet () during operation and let the gas pass through the ozone generation device () and the activated carbon purification unit () to be discharged from the air outlet () into the room. 1. An air purifier , comprising:a housing formed with an air duct, the air duct comprising an air inlet and an air outlet, and the air outlet is disposed indoors;an ozone generation device and an activated carbon purification unit, the ozone generation device and the activated carbon purification unit being provided in the air duct along a direction from the air inlet to the air outlet, the ozone generation device for generating ozone; anda fan provided in the air duct, the fan is configured for sucking air from the air inlet during operation and allowing the air to pass through the ozone generation device and the activated carbon purification unit to be discharged from the air outlet into a room.2. The air purifier according to claim 1 , wherein an exhaust direction of the air outlet is directed upward; orthe exhaust direction of the air outlet is toward a side that the air purifier is located; orthe purified gas is discharged into a cupboard by the air outlet.3. The air purifier according to claim 1 , wherein a kitchen ventilator comprises an air purification module disposed above the fan claim 1 , the air purification module comprises a purification housing claim 1 , the ozone generation device claim 1 , and the activated carbon ...

OZONE CELL POWER SUPPLY APPARATUS AND METHOD

The present invention generally includes an ozone generation system with a power supply that measures the rate of energy delivered to the ozone generation cell. While changing voltage, frequency or current will likely affect the rate of energy delivery, current, frequency and voltage provide a very poor and unreliable control for an ozone generation cell. It is only through control of the rate of energy delivery that consistent, reliable ozone generation is possible. Based upon the measurements of the rate of energy delivery as measured at the ozone generation cell, compared to the rate of energy delivery supplied, the rate of energy delivery supplied can be adjusted to improve ozone production and control. 1. An ozone generation system , comprising:an ozone generation cell;a current transformer coupled to the ozone generation cell;a comparator coupled to the current transformer;a switching device driver coupled to the current transformer;a voltage controlled oscillator coupled to the switching device driver;an adder coupled to the voltage controller oscillator; anda flip flop coupled to the comparator and the adder.2. The ozone generation system of claim 1 , wherein the flip flop is coupled between the voltage controlled oscillator and the switching device driver.3. The ozone generation system of claim 2 , further comprising an integrator coupled between the adder and the voltage controlled oscillator.4. The ozone generation system of claim 3 , further comprising one or more switching device coupled to the switching device driver.5. The ozone generation system of claim 4 , further comprising:a choke and capacitor coupled the one or more switching device; anda step up transformer coupled to the choke and capacitor and to the current transformer.6. The ozone generation system of claim 5 , further comprising:a voltage supply;a current sensing resistor coupled to the voltage supply and the one or more switching device; anda differential amplifier coupled to the current ...

Piezoelectric Transformer

A piezoelectric transformer is disclosed. In an embodiment a piezoelectric transformer includes an input region and an output region, wherein the input region is configured to convert an AC voltage into a mechanical oscillation, wherein the output region is configured to convert a mechanical oscillation into an electrical voltage, wherein the piezoelectric transformer includes a longest edge and a shortest edge, and wherein the longest edge includes a length that is twenty times a length of the shortest edge or less.

Ozone generator

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.

PORTABLE OZONIZING DEVICE

An ozonizing device comprises a box-shaped body which encloses therein ventilation device, a discharge ozone generator, an ozone-catalysing UV-C lamp and an additional ozone generator. The box-shaped body comprises a partition wall intended to define two distinct chambers in said box-shaped body: a first chamber in which the ventilation device, the discharge ozone generator and the ozone-catalysing UV-C lamp are housed, and a second chamber in which the further ozone generator is housed which is interfaced with air distribution device associated with a diffuser tube for the diffusion of an ozone-enriched air flow. The ozonizing device further comprises a control unit configured so as to selectively activate, alone or in combination, each of the discharge ozone generator, ozone-catalysing UV-C lamp and the additional ozone generator. 1. An ozonizing device comprising a box-shaped body which encloses therein a ventilation device , a discharge ozone generator , an ozone-catalysing UV-C lamp for destroying ozone , and an additional ozone generator , the box-shaped body including a partition wall which is intended to define two different chambers in the box-shaped body , a first chamber in which the ventilation device , the discharge ozone generator and the ozone-catalysing UV-C lamp are received and a second chamber , in which the additional ozone generator is received , said additional ozone generator being interfaced with air distribution device which is associated with a diffuser tube for diffusing an air flow which is enriched with ozone outside said ozonizing device by said diffuser tube , said first chamber being configured in such a manner that an air flow through said box-shaped body is defined , the ozonizing device further comprising a control unit which is configured so as to selectively activate , alone or in combination , each of said discharge ozone generator , ozone-catalysing UV-C lamp and additional ozone generator.2. The ozonizing device according to ...

Ozone generator

There is provided a generator (1) for forming ozone from air. The generator is adapted to be connected to a power source and comprises a unitary grid assembly (see Figs. 2 and 3) which includes a first dielectric plate (32), a second dielectric plate (34) spaced apart from the first dielectric plate (32), a wire mesh anode (42) located between the first and the second dielectric plates (32 and 34), a third dielectric plate (36) spaced from the second dielectric plate (34), a cathode plate (44) located between the second and the third dielectric plates (34 and 36), and a pair of dielectric spacers (38 and 40) located between the second dielectric plate (34) and the cathode plate (44). The second dielectric plate (34), the pair of spacers (34), the pair of spacers (38 and 40), and the cathode (44) define a space (50) for the passage of air and the collection of ozone formed from the air. The generator also comprises a blower (10) positioned spaced from but adjacent the grid assembly, for moving the air through the space (50).

Low temperature micro plasma ozone generating device

A low temperature micro plasma ozone generating device for generating ozone by inhaling external air and reacting the sucked air with plasma. The low temperature micro plasma ozone generating device includes a main body having an accommodating space therein; an ozone generating module installed in an internal accommodation space of the main body to generate ozone; an external air supply line installed to be connected to the ozone generating module from an outside of the main body and configured to supply external air of the main body to an inside of the ozone generating module; an ozone discharge line installed to extend from the inside of the ozone generating module to the outside of the main body to discharge the ozone generated by the ozone generating module to the outside of the main body; and a cooling fan installed on one side of the main body.

Ozoniser and method for producing ozone from oxygen

The present invention relates to an ozoniser comprising a first and a second electrode between which a first dielectric is arranged, wherein between the first dielectric and the first electrode, a gas channel is arranged, through which an oxygen-containing gas can be conveyed, wherein a first cooling-fluid channel is provided, the wall of which is formed at least in sections by the first dielectric or the second electrode. In order to provide an ozoniser that can realize an increased ozone yield compared to the known devices, it is proposed according to the invention that the cooling-fluid channel is filled with a porous material.

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 development apparaus

본 발명은 오존발생장치에 관한 것으로서, 특히 공진회로를 이용하여 고주파를 방전함으로써, 내부전극의 내식성과 방열 효과를 향상시키는 오존발생장치에 관한 것으로, 외부 전원으로부터 인가된 전압을 공진회로를 사용하여 고전압 임펄스파를 발생시키는 전자회로부와, 상기 전자회로부에서 인가하는 고전압 임펄스파를 이용하여 내부로 유입되는 공기를 방전하여 오존을 생성하는 방전실과; 상기 전자회로부와 방전실의 사이에 위치하여 특정온도 이상이 되면 상기 방전실로 인가되는 고전압 임펄스파를 차단시키는 동작을 수행하는 동작감지수단으로 구성한 장치를 제공함으로써, 임펄스파를 방전실에 인가하여 소비전력을 최소화하면서 한 쌍의 고전압 전극판과 접지된 방전실 벽 사이에 다수의 번개가 형성되어 방전이 일어나게 하여, 오존 생성율을 높이는 효과와; 방전실의 구조가 평판형으로 이루어져 소형화가 용이하고, 고전압 전극의 외부 표면적이 넓어서 오존 발생율을 높이며, 자연 공냉에 의한 열방산이 용이하여 부피가 큰 별도의 냉각장치가 필요하지 않아 소형화가 가능한 등의 효과가 있다. The present invention relates to an ozone generator, and more particularly, to an ozone generator for improving the corrosion resistance and heat dissipation effect of an internal electrode by discharging high frequency by using a resonance circuit. An electronic circuit unit for generating a high voltage impulse wave, and a discharge chamber for generating ozone by discharging air introduced therein by using the high voltage impulse wave applied by the electronic circuit unit; It is located between the electronic circuit unit and the discharge chamber and provided with a device consisting of the operation sensing means for performing the operation to block the high voltage impulse wave applied to the discharge chamber when the temperature is above a certain temperature, by applying the impulse wave to the discharge chamber A plurality of lightning is formed between the pair of high voltage electrode plates and the grounded discharge chamber wall while minimizing the electric power to cause discharge, thereby increasing the ozone generation rate; The structure of the discharge chamber is flat, making it easy to miniaturize, and the external surface area of the high voltage electrode is wide, which increases the ozone generation rate, and the heat dissipation by natural air cooling is easy. It works.

Способ получения озона и его генератор

Изобретение относится к способам и устройствам для получения озона. Генератор озона содержит помещенный в корпус пакет чередующихся повернутых относительно друг друга на 180 градусов и заключенных в диэлектрическую прокладку электродов с высоким и нулевым электрическим потенциалом. Электроды выполнены в виде круглых стержней. Диэлектрическая прокладка выполнена в виде плоской решетки, в прутьях которой размещены электроды. В плоской решетке помещают не менее трех электродов в одной плоскости на расстоянии между каждым из них не менее пяти и не более десяти величин ширины электрода. В качестве материала для изготовления диэлектрической прокладки использована теплопроводная керамика. Параллельно диэлектрической прокладке могут быть размещены дополнительные диэлектрические прокладки, выполненные в виде решетки, шаг прутьев которых равен шагу прутьев основной решетки. В прутьях решетки дополнительной диэлектрической прокладки размещен пакет чередующихся повернутых относительно друг друга на 180 градусов и заключенных в диэлектрическую прокладку электродов с высокими и нулевым электрическим потенциалом, а прутья основной и дополнительных решеток смещены относительно друг друга в горизонтальной плоскости на половину шага прутьев. Расстояние между электродами основной и дополнительной прокладки выполнено не менее пяти и не более десяти величин ширины электрода для обеспечения взаимокоронирования основного и дополнительного разряда и принято равным величине шага прутьев. Электроды подсоединены к генератору импульсов. 4 ил. 063790с ПЧ ГЭ РОССИЙСКОЕ АГЕНТСТВО ПО ПАТЕНТАМ И ТОВАРНЫМ ЗНАКАМ (19) (51) МПК ВИ” 2 064 890 ' 13) Сл С 01 В 13/11 12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ РОССИЙСКОЙ ФЕДЕРАЦИИ (21), (22) Заявка: 93053302/26, 26.11.1993 (46) Дата публикации: 10.08.1996 (56) Ссылки: 1. Авторское свидетельство СССР М 1754648, кл. СО1 В 1ЗЛ/Т, 1990. 2. Патент США М 3801791, кл. С О1 В 13ЛЯ2, 1964. 3. Авторское свидетельство СССР М 941218, кл. С 01 В 13/1, 1980. (71) Заявитель: ...

Apparatus for generating ozone in high concentration

본 발명은 고농도 및 고효율로 오존을 발생시키며 오존 발생 농도를 선형적으로 조절할 수 있는 고농도 오존 발생 장치에 관한 것이다. 고농도 오존 발생 장치는 산소 발생기, 평판형 오존 발생기, 고전압 트랜스 포머, 고주파 인버터, 냉각수 공급기, 제어 신호 발생기를 포함하고 있다. 고주파 인버터는 제어 신호 발생기로부터 입력되는 제어 신호의 전압에 대응하는 사전설정된 온-오프(on-off) 시간 간격에 따라 발생된 고주파 고전압 펄스를 고전압 트랜스포머를 통해 평판형 오존 발생기에 인가함으로써 발생되는 오존 농도를 선형적으로 조절한다. 평판형 오존 발생기는 고유전율을 갖는 평판형 세라믹을 절연체로 이용한 구조이므로 내구성이 높을 뿐만 아니라 소형으로 제작될 수 있다. The present invention relates to a high concentration ozone generating device capable of generating ozone at high concentration and high efficiency and linearly adjusting the ozone generating concentration. The high concentration ozone generator includes an oxygen generator, a flat ozone generator, a high voltage transformer, a high frequency inverter, a cooling water supply, and a control signal generator. The high frequency inverter generates ozone by applying a high frequency high voltage pulse generated at a predetermined on-off time interval corresponding to the voltage of the control signal input from the control signal generator to the flat plate ozone generator through the high voltage transformer. Adjust the concentration linearly. The flat plate type ozone generator has a structure having a high dielectric constant and a flat plate type ceramic as an insulator, so that the plate type ozone generator is not only high in durability but also small in size.

오존발생장치

본 발명은 오존발생장치에 관한 것으로서, 특히 공진회로를 이용하여 고주파를 방전함으로써, 내부전극의 내식성과 방열 효과를 향상시키는 오존발생장치에 관한 것으로, 외부 전원으로부터 인가된 전압을 공진회로를 사용하여 고전압 임펄스파를 발생시키는 전자회로부와, 상기 전자회로부에서 인가하는 고전압 임펄스파를 이용하여 내부로 유입되는 공기를 방전하여 오존을 생성하는 방전실과; 상기 전자회로부와 방전실의 사이에 위치하여 특정온도 이상이 되면 상기 방전실로 인가되는 고전압 임펄스파를 차단시키는 동작을 수행하는 동작감지수단으로 구성한 장치를 제공함으로써, 임펄스파를 방전실에 인가하여 소비전력을 최소화하면서 한 쌍의 고전압 전극판과 접지된 방전실 벽 사이에 다수의 번개가 형성되어 방전이 일어나게 하여, 오존 생성율을 높이는 효과와; 방전실의 구조가 평판형으로 이루어져 소형화가 용이하고, 고전압 전극의 외부 표면적이 넓어서 오존 발생율을 높이며, 자연 공냉에 의한 열방산이 용이하여 부피가 큰 별도의 냉각장치가 필요하지 않아 소형화가 가능한 등의 효과가 있다.

Ozone generator

Ozone generator

Ozone generator

Может быть использовано для получения озона на основе импульсного коронного разряда. Озонатор для получения озона в импульсном коронном разряде содержит коронирующий и некоронирующий электроды, при этом некоронирующий электрод (по крайней мере его часть, контактирующая с разрядом) сделан из алюминия или сплава алюминия (или из проводящего сплава с теплопроводностью выше 50 Вт/м • град), источник импульсов высокого напряжения с функцией включения/выключения высокого напряжения обеспечивает удельную мощность импульсного коронного разряда более 50 Вт/л, частота следования импульсов превышает 500 Гц, отношение амплитуды импульсов высокого напряжения к амплитуде остаточного постоянного напряжения между импульсами составляет 1,5-3. Изобретение позволяет осуществить повышение концентрации озона - более 20 г/нм 3 (необходимой для практического применения озонатора) при минимальной энергетической цене генерации озона (на уровне 10 кВт • час/кг озона) в озонаторе на основе импульсного коронного разряда. 1 з.п.ф-лы, 2 ил. эфуебггс пы ГЭ РОССИЙСКОЕ АГЕНТСТВО ПО ПАТЕНТАМ И ТОВАРНЫМ ЗНАКАМ (19) ВИ” 21419 446 ' (51) МПК 13) Сл С 01 В 13/11 12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ РОССИЙСКОЙ ФЕДЕРАЦИИ (21), (22) Заявка: 96120575/25, 10.10.1996 (46) Дата публикации: 27.09.1998 (56) Ссылки: 1. 4Р 3-64443 В, 15.12.82. 2. $Ц 1564113 АЛ, 04.01.88. 3. 4Р 4-15162 А, (71) Заявитель: Аболенцев Виктор Алексеевич, Коробцев Сергей Владимирович, Медведев Дмитрий Дмитриевич, Ширяевский Валерий Леонардович 17.03.92. 4. СВ 1600055, 15.11.78. 5. (72) Изобретатель: Аболенцев Виктор Алексеевич, Ргосее4тд$ ог |тегпаНопа! О7хопе Коробцев Сергей Владимирович, Медведев Зутроз!ит, У/агзами, Ро!апа, 1994. Дмитрий Дмитриевич, Ширяевский Валерий Леонардович (73) Патентообладатель: Аболенцев Виктор Алексеевич, Коробцев Сергей Владимирович, Медведев Дмитрий Дмитриевич, Ширяевский Валерий Леонардович (54) УСТРОЙСТВО ДЛЯ ПОЛУЧЕНИЯ ОЗОНА (57) Реферат: концентрации озона - более 20 Может быть использовано для получения ...

Apparatus for producing ozone

FIELD: ozone production. SUBSTANCE: apparatus comprises high-voltage source and at least two spaced-apart planar electrodes. Dielectric material is interposed between both electrodes in such manner as to form at least one path for electric current flow. Novelty of apparatus resides in that at least one of planar electrodes is capable of vibrating, and it consists of two layers of electroconductive material, one layer of which is capable to vibrate. Both layers are separated by material with spring/damping effect and are secured in such manner as to permit vibration of electrodes. EFFECT: higher efficiency. 15 cl, 4 dwg всссо0тс ПЧ ГЭ РОССИЙСКОЕ АГЕНТСТВО ПО ПАТЕНТАМ И ТОВАРНЫМ ЗНАКАМ ЗВИ“” 2103 225 Сл (51) МПК С 01 В 13/11 12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ РОССИЙСКОЙ ФЕДЕРАЦИИ (21), (22) Заявка: 93058273/25, 11.12.1992 (30) Приоритет: 12.12.1991 ОЕ Р 4141025.4 (46) Дата публикации: 27.01.1998 (56) Ссылки: 1. ОЕ, заявка, 2644978, кл. С 01 В ЗАТ, 1983. 2. ОЕ, патент, 299248, кл. С 01 В 1З/1Л, 19715. (86) Заявка РСТ: ЕР 92/02875 (11.12.92) (71) Заявитель: Манфред Римплер[0Е] (72) Изобретатель: Манфред Римплер[0Е] (73) Патентообладатель: Манфред Римплер[ОЕ] (54) УСТРОЙСТВО ДЛЯ ПОЛУЧЕНИЯ ОЗОНА (57) Реферат: Использование: в устройствах для получения озона. Устройство для производства озона выполнено с источником высокого напряжения и по меньшей мере двумя расположенными на расстоянии друг от друга ПЛОСКИМИ электродами С расположенными между ними для образования по меньшей мере одного пути протекания диэлектриком, причем, по меньшей мере один из плоских электродов способен вибрировать, плоский электрод состоит из двух слоев электропроводного материала, из которых по меньшей мере один слой способен вибрировать, между обоими слоями расположен материал, действующий пружинно-демпфирующим образом, и оба слоя закреплены для обеспечения возможности вибраций электродов. 14 з.пП. ф-лы, 4 ИЛ. РГ, 1 2103225 С1 КО всссо0тс ПЧ ГЭ (19) 13) ВИ ” 2103 225' (51) п. С1.6 С Ол В 13/11 СЛ ...

High density ozonizer

본 발명은 고농도 오존발생장치에 관한 것으로, 산소(O 2 )를 고압방전에 의해 오존(O 3 )으로 변환시키는 장치에서 고압방전에 의해 생성된 열을 효과적으로 제거시켜줄 수 있도록, 오존발생장치 몸체(101) 내부의 접지전극파이프(102)외측에 암모니아 또는 프레온가스를 충진시킨 자켓(111)을 설치함과 아울러 이 자켓(111)의 외측면에는 방열핀(112)을 부착한 것으로, 암모니아 또는 프레온 가스가 충진된 자켓(111) 및 방열핀(112)에 의하여 신속한 열교환이 이루어지도록 하므로써 효율적으로 고농도의 오존(O 3 )을 생성시킬 수 있도록 한 것이다. The present invention relates to a high-concentration ozone generator, to effectively remove heat generated by high-pressure discharge in the device for converting oxygen (O 2 ) into ozone (O 3 ) by high pressure discharge, the ozone generator body ( 101. A jacket 111 filled with ammonia or freon gas is installed outside the ground electrode pipe 102 and a heat dissipation fin 112 is attached to the outer surface of the jacket 111. It is to be able to efficiently generate a high concentration of ozone (O 3 ) by allowing a rapid heat exchange by the jacket 111 and the heat radiation fins 112 is filled.

Ozone Generator

본 발명은 오존 발생기에 관한 것으로, 보다 구체적으로 내주 면에 고전압전극층이 부착되어 있는 유전체관 및 상기 유전체관의 외주 면과 이격되어 방전 공간을 형성하는 접지전극부를 포함하는 오존발생기에 있어서, 상기 유전체관은 외부공기가 통하도록 내부가 중공형태이고, 양 끝단부의 직경이 작아지는 형상이며, 상기 접지전극부는 일영역에 원료 가스 주입구 및 오존 배출구를 구비하고, 복수의 중앙이 비어 있는 판상의 접지전극 유닛에 중앙이 비어 있는 판상의 절연판 유닛이 각각 사이에 위치하는 오존 발생기에 관한 것이다. The present invention relates to an ozone generator, and more particularly, to an ozone generator including a dielectric tube having a high voltage electrode layer on an inner peripheral surface thereof and a ground electrode portion spaced apart from an outer circumferential surface of the dielectric tube to form a discharge space, The ground electrode has a material gas inlet and an ozone outlet in one region. The ground electrode has a plate-shaped ground electrode having a plurality of centers, And a plate-like insulating plate unit in which a center is empty in the unit is located between the plates.

An ozone discharge tube and an ozone generation apparatus using it

본 발명은 오존발생특성이 가스원료의 투입량에 관계없이 안정화되도록 한 오존방전관 및 그 오존방전관을 이용하여 환경오염을 해소하도록 한 오존발생장치에 관한 것으로, 고주파 전원이 인가되는 일정 형상의 내부 전극, 상기 내부 전극과 일정 간격을 두고서 상기 내부 전극을 감싸는 외부 전극, 상기 내부 전극과 외부 전극간의 무성 코로나방전에 의해 오존을 생성시키는 소정 갭의 방전공간, 방전관 내부전극과 외부전극간 소정 갭을 일정하게 유지시키기 위한 스페이서를 구비한 오존방전관 및 상기 오존방전관에 일정한 고주파 전원을 제공하는 전원공급수단을 구비하여, 고기압 영역의 오존방전관에 고주파 전원을 인가함으로써 오존발생특성이 가스원료의 투입량에 관계없이 안정화시키는 매우 유용한 발명인 것이다. The present invention relates to an ozone discharge tube in which ozone generation characteristics are stabilized irrespective of the input amount of a gas raw material, and an ozone generating device to solve environmental pollution by using the ozone discharge tube. An outer electrode surrounding the inner electrode at a predetermined distance from the inner electrode, a discharge space having a predetermined gap for generating ozone by an a silent corona discharge between the inner electrode and the outer electrode, and a predetermined gap between the inner electrode of the discharge tube and the outer electrode Ozone discharge tube having a spacer for maintaining and a power supply means for providing a constant high frequency power to the ozone discharge tube, by applying a high frequency power to the ozone discharge tube in the high pressure region to stabilize the ozone generation characteristics irrespective of the input amount of gas raw material It is a very useful invention.

Silent discharge type plasma device

在本发明的无声放电式等离子体产生装置包括电介体、夹着电介体而相对地配置的1组电极、向电极之间施加交流电压而使其放电的交流电源，向产生放电的放电空间供给气体而形成等离子体。电极的至少一个由形成在电介体上的导电性供电薄膜构成，在电介体破损而在电极之间产生了电弧放电的情况下，使产生了电弧放电的部分的供电薄膜消失或氧化，使得停止产生电弧放电。

Ozone Apparatus

본 발명은 소비전력을 낮춤과 아울러 오존의 농도를 높이기 위한 오존 발생장치에 관한 것이다. The present invention relates to an ozone generator for lowering power consumption and increasing ozone concentration. 본 발명의 오존 발생장치는 전극관과, 전극관이 내부에 삽입되는 절연관과, 절연관의 외주면에 나선 형태로 감겨지는 전극 스프링과, 절연관 상에서 전극 스프링을 고정시키기 위한 고정부재를 구비한다. The ozone generating device of the present invention includes an electrode tube, an insulating tube into which the electrode tube is inserted, an electrode spring wound in a spiral form on the outer circumferential surface of the insulating tube, and a fixing member for fixing the electrode spring on the insulating tube. . 이러한 구성에 의하여, 본 발명에 따른 오존 발생장치는 소비전력을 낮춤과 아울러 오존의 농도를 높이게 된다. By such a configuration, the ozone generating device according to the present invention can lower the power consumption and increase the concentration of ozone.

Ozone generator in the form of cylindric spirals, methods for ozone generation, and fabrication of generator

Устройство и способ для получения высокой концентрации газообразного озона, использующие электрические коронный разряд в присутствии газа, содержащего кислород. Генератор содержит первый и второе электроды, разделенные диэлектрической трубкой, каждые электрод имеет средства для присоединения к высоковольтному источнику напряжения переменного тока. Первый электрод предпочтительно имеет решетчатую структуру и окружает диэлектрическую трубку. Второй электрод выполнен в виде массы цилиндрических спиралей со множеством искривленных поверхностей. Второй электрод расположен внутри диэлектрической трубки, расположенной под первым электродом. На искривленных поверхностях цилиндрических спиралей создается коронный разряд. В одном из вариантов выполнения генератора озона масса цилиндрических спиралей снабжена по меньшей мере одной мелкоячеистой губкой, имеющей множество слоев непрерывной цилиндрической спирали, расположенной в общем спиральном направлении вокруг центральной оси мелкоячеистой губки. Масса цилиндрических спиралей облегчает перемешивание протекающего сквозь них газа, содержащего кислород. Генератор обеспечивает высокой концентрации получение озона, выделяя при этом малое количество побочного тепла, и имеет простую, надежную и прочную конструкцию.

Ozonizer

Изобретение относитс  к устройствам дл  озонировани  и может быть использовано в энергетике дп  интен- сификации сжигани  топлива, газовой электротехники и электрохимических методов обработки газосодержащих систем. Целью изобретени   вл етс  повьшение эффективности озонатора путем увеличени  эмиттирующей способности коронируницего электрода и перераспределени  кислородсодержащих молекул газа на выходе. В корпусе озонатора размещены подключенный к отрицательному полюсу источника высокого напр жени  коронирующий электрод , выполненный в виде закрепленных на металлической стойке овальных пластин с заостренными кра ми и не- коронирующий электрод - в виде жело- - ба с отогнутыми кра ми, подключенного к положительному полюсу источника напр жени . В выходной патрубок . вмонтирована металлическа  втулка с диэлектрическим покрытием, подключенна  к положительному полюсу источника напр жени , и коаксиальный отвод щий патрубок, В зоне коронного разр да осуществл етс  предельна  зар дка всех молекул кислорода с их диссо1р ацией и последующим синтезом в зар женные молекулы озона, которые в выходном патрубке прит гиваютс  к стенкам металлической втулки, а нейтрально зар женные молекулы азота вытесн ютс  в центральную часть и вывод тс  через отвод щий патрубок. В озонаторе эмиттируинда  способность коронирующего электрода увеличена в 5 раз, а многократна  ионизаци  воа- духа обуславливает повышение концентрации озона. 4 ил. 2 табл. (П 00 ел ел 05 The invention relates to devices for ozonation and can be used in the power industry in dp of intensification of fuel combustion, gas electrical engineering and electrochemical methods for treating gas-containing systems. The aim of the invention is to increase the efficiency of the ozonizer by increasing the emitting capacity of the coronary electrode and redistributing oxygen-containing gas molecules at the outlet. A corona electrode connected to the negative pole of a high voltage source, made in the form of oval plates with pointed ...

A discharge-electrode of an ozonizer system

본 발명은 오존발생장치용 방전전극에 관한 것으로서, 외부 전극으로 사용되는 스테인레스 파이프(stainless pipe)(11); 상기 스테인레스 파이프(11)의 내부에 구비된 제 1 파이렉스(Pyrex) 유리관(13); 상기 제 1 파이렉스(Pyrex) 유리관(13)의 내측에, 상호 동일축을 갖도록 위치하는 제 2 파이렉스(Pyrex) 유리관(15); 상기 제 2 파이렉스(Pyrex) 유리관(15)의 내측에 구비되어 중심 전극으로 사용되는 스테인레스 파이프(17); 및 상기 제 1 파이렉스(Pyrex) 유리관(13)의 내주에 권취되어 중간전극으로 사용되는 나선형 전선(spiral stainless wire)(19)을 포함하여 구성되어, 동일한 에너지를 사용하면서도 보다 고농도/고수율의 오존을 발생시킬 수 있어서 전력소비를 줄일 수 있게 되는 유용한 발명이다. The present invention relates to a discharge electrode for an ozone generating device, comprising: a stainless pipe (11) used as an external electrode; A first Pyrex glass tube 13 provided inside the stainless pipe 11; A second Pyrex glass tube 15 positioned inside the first Pyrex glass tube 13 to have the same axis as each other; A stainless pipe 17 provided inside the second Pyrex glass tube 15 and used as a center electrode; And a spiral stainless wire 19 wound around the inner circumference of the first Pyrex glass tube 13 and used as an intermediate electrode, and using the same energy but having a higher concentration / high yield of ozone. It can be generated is a useful invention that can reduce the power consumption.

Piezoelectric transformer

본 발명은 입력부(2)와 출력부(3)를 구비하는 피에조 전기 변압기(1)에 관한 것이며, 상기 입력부(2)는 공급된 교류 전압을 기계 역학적 진동으로 전환하도록 형성되어 있고, 상기 출력부(3)는 이러한 기계 역학적 진동을 전압으로 전환하도록 형성되어 있으며, 또한, 상기 피에조 전기 변압기(1)는 최장 에지(13) 및 최단 에지(14)를 구비하며, 상기 최장 에지(13)는 상기 최단 에지(14)의 길이에 대해 최대 20배 긴 길이를 구비하는 것을 특징으로 한다. The present invention relates to a piezoelectric transformer (1) having an input (2) and an output (3), the input (2) is formed to convert the supplied AC voltage into mechanical mechanical vibration, the output (3) is formed to convert such mechanical vibration into a voltage, and the piezoelectric transformer 1 has a longest edge 13 and a shortest edge 14, and the longest edge 13 is the It is characterized by having a length of up to 20 times longer than the length of the shortest edge 14.

Ozone generating tube and ozone generating apparatus

본 발명은 오존발생관 및 오존발생장치에 관한 것으로, 그 구성은 내부전극; 상기 내부 전극을 감싸는 유전체; 상기 유전체와 일정 간격 이격된 상태로 감싸며 방전공간을 갖는 외부전극; 상기 내부전극을 관통하는 냉각부;를 포함하여 이루어지는 오존발생관; 상기 오존발관 측으로 산소를 공급하는 산소발생부; 및 상기 냉각부에서 배출되는 냉각재를 필터링하여 배출하는 배출부;를 포함하여 이루어지며, 상기 외부전극 내에서는 산소가 공급되어 고전압에 의해 오존을 발생하고, 상기 냉각부에는 냉각재가 공급되어 각각의 전극에서 발생된 열을 냉각하게 한다. 본 발명에 따르면, 오존 또는 공기 중에 포함된 질소를 이용해 오존발생관 내부를 관통하는 냉각라인을 형성시켜 전극 측을 직접 방열있게 함으로써 공간을 최소한으로 이용하며 냉각 효율을 극대화할 수 있게 하는 효과가 있다. 오존, 공기, 산소, 질소, 산소발생부, 냉각

Apparatus for the formation of excited or instable gaseous molecules and use of said apparatus

Ozone generator

FIELD: treatment of gas flow by electric discharge for production of ozone-air or ozone-oxygen mixture. SUBSTANCE: ozone generator has electrode plates with terminals positioned one opposite to other with formation of discharge gap between them hermetically isolated from electrodes by dielectric plates. Electrode plates are located on external surfaces of dielectric plates which are placed at some fixed distance one from another with the aid of insert which geometric dimension corresponds to this distance. Electrode plate can be pressed against dielectric plates by means of spring-loaded fixtures. EFFECT: enhanced operational efficiency. 1 cl, 1 dwg СсссСоОтс ПЧ ГЭ РОССИЙСКОЕ АГЕНТСТВО ПО ПАТЕНТАМ И ТОВАРНЫМ ЗНАКАМ (19) (51) МПК ВИ” 2102 312‘ 13) Сл С 01 В 13/11 12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ РОССИЙСКОЙ ФЕДЕРАЦИИ (21), (22) Заявка: 96106937/25, 08.04.1996 (46) Дата публикации: 20.01.1998 (56) Ссылки: 1. 45, патент, 3801791, кл. С 01 В ЗАЛ, 1976. 2. ЗидитЁзи На@оз её а1. Спептса! геаспоп т Нет еес пс Ч!зсрагдае |. Те теспап!зт о! охопе ТогиаНоп "Ви|.СПпет.Зос.4ар". - 1970, 43, М 7, р.1921 - 1933. (72) (71) Заявитель: Захаров Александр Леонидович, Колобков Вадим Петрович, Суворов Анатолий Николаевич, Поляков Петр Алексеевич Николаевич, Поляков Петр Алексеевич (73) Патентообладатель: Захаров Александр Леонидович, Колобков Вадим Петрович, Суворов Анатолий Николаевич, Поляков Петр Алексеевич Изобретатель: Захаров Александр Леонидович, Колобков Вадим Петрович, Суворов Анатолий (54) ГЕНЕРАТОР ОЗОНА (57) Реферат: Использование: обработка потока газа электрическим разрядом для получения озоно-воздушной или озоно-кислородной смеси. Генератор озона содержит электродные пластины С клеммами установленные напротив друг друга с образованием между ними разрядного промежутка, герметично изолированного от электродов диэлектрическими пластинами, причем электродные пластины расположены на наружных поверхностях диэлектрических пластин, которые установлены на зафиксированном друг от ...

EASY SPARKLESS ELECTRODE FOR OZONE PRODUCTION

1. Система электродов для генератора озона с трубообразным внешним электродом (1), который концентрически и на расстоянии окружает трубообразный диэлектрик (2), причем диэлектрик (2) окружает на расстоянии концентрически стержень (3), при этом в промежуточном пространстве между внешним электродом (1) и диэлектриком (2) расположен наполнитель (4) и в промежуточном пространстве между диэлектриком (2) и стержнем (3) расположен наполнитель (5), отличающаяся тем, что стержень (3) выполнен в виде изолятора, а наполнитель (5) выполнен в виде внутреннего электрода.2. Система электродов по п.1, отличающаяся тем, что стержень (3) выполнен цельным.3. Система электродов по п.1, отличающаяся тем, что стержень (3) выполнен полым.4. Система электродов по любому из пп.1-3, отличающаяся тем, что стержень (3) выполнен круглым.5. Система электродов по любому из пп.1-3, отличающаяся тем, что стержень (3) выполнен из стекла.6. Система электродов по любому из пп.1-3, отличающаяся тем, что наполнитель (4) и наполнитель (5) выполнены из сплетенного из проволоки полотна.7. Система электродов по любому из пп.1-3, отличающаяся тем, что наполнитель (5) в промежуточном пространстве между диэлектриком (2) и стержнем (3) выполнен с разъемом для электрического источника питания.8. Система электродов по любому из пп.1-3, отличающаяся тем, что расположенный в центре системы электродов стержень (3) выполнен из стекла или из другого материала, совместимого с кислородом или озоном. РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2013 138 444 A (51) МПК C01B 13/11 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ЗАЯВКА НА ИЗОБРЕТЕНИЕ (21)(22) Заявка: 2013138444/05, 16.01.2012 (71) Заявитель(и): КСИЛЕМ АйПи ХОЛДИНГЗ ЛЛК (US) Приоритет(ы): (30) Конвенционный приоритет: 19.01.2011 DE 102011008947.0 (85) Дата начала рассмотрения заявки PCT на национальной фазе: 19.08.2013 R U (43) Дата публикации заявки: 27.02.2015 Бюл. № 6 (72) Автор(ы): ФИТЦЕК Райнер (DE), БИЛЛИНГ Эрнст Мартин (DE), ФИКЕНС Ральф ...

A discharge tube for the ozone generator comprised of a pair of cap

본 발명은 복수의 돌출부를 갖는 캡을 사용하여, 돌출부가 방전 공간의 간격보다 두꺼운 두께를 가져 스페이서 역할을 함으로써 더욱 안정적인 방전 공간 형성 및 조립이 용이한 오존 발생 장치용 방전관을 제공하고, 또한 복수의 쌍을 이루는 홈부를 갖는 캡과 홈부 및 전극관 사이에 삽입되는 굴곡부를 갖는 스페이서를 사용하여, 비교적 정확한 방전 공간 간격 형성과 조립이 용이한 오존 발생 장치용 방전관을 제공한다. The present invention provides a discharge tube for an ozone generator in which a projection having a plurality of protrusions has a thickness larger than that of a discharge space and serves as a spacer to facilitate a more stable formation and assembly of a discharge space, Provided is a discharge tube for an ozone generator which is relatively easy to form and assemble with a relatively precise spacing of discharge spaces by using a spacer having a pair of groove portions and a spacer having a bent portion inserted between the groove portion and the electrode tube.

Ozonizer having a display unit

PURPOSE: To provide an ozonizer having display function by patterning electrodes such that the contour of prescribed patterns is formed on the electrodes or coating a fluorescent substance on an expected area of the electrodes while using structure of a creeping electric discharge type ozonizer as it is. CONSTITUTION: The ozonizer having display function comprises a main dielectric(12); a first electrode(13) formed at one side of the main dielectric; and a second electrode(14) formed at the other side of the main dielectric, wherein ozone is generated by impressing a power supply to the first electrode and the second electrode, thereby generating a corona creeping electric discharge, one or more of the first electrode and the second electrode are patterned in such a way that the contour of the electrodes has prescribed patterns to have the patterns light emitted and displayed to the outside during corona creeping electric discharge, and wherein a fluorescent substance layer is formed on a layer on which the patterned electrodes are formed so that influence of ultraviolet rays generated by the corona creeping electric discharge stimulate the fluorescent substance to display fluorescent substance patterns(18) to the outside.

Ozone generator driven by pulse width modulation system

본 발명은 오존 발생 장치에 있어서, 외주면에 유전체가 코팅되고 양쪽의 단부는 캡 지지부(110, 110a)를 구비하여 제1 전극(70)과 연결되는 유전체 튜브(10)와; 상기 유전체 튜브(10)를 내부에 수용하며 일정한 간격의 방전공간(S)을 형성하며 제2 전극(80)과 연결되는 방전 튜브(20)와;상기 방전 튜브(20)를 내부에 수용하며 워터재킷을 형성하는 케이스(40)와; 상기 유전체 튜브(10), 방전 튜브(20), 단열튜브(30) 및 케이스(40)가 이루는 조립체의 양쪽 단부를 지지하는 한 쌍의 캡(50, 50a)과; 상기 한 쌍의 캡(50, 50a)을 상기 유전체 튜브(10)에 고정하기 위한 고정수단(60)과; 전원공급부(140)로부터 전력을 공급받아 상기 제1, 2 전극(70, 80)에 펄스형 구동신호를 인가하는 전력제어부(130);를 포함하는 것을 특징으로 하는 발열성 및 내구성이 개선된 저전력 오존 발생 장치에 관한 것이다.

oxygen atom generators of nozzle for pest control machine

본 발명은 무동력 풍향 기능을 갖는 병해충 방제기용 산소원자 발생기 노즐에 관한 것으로, 더욱 구체적으로는 산소원자를 안정적이면서 다량으로 생성할 수 있도록 하여 수산기(OH-)의 발생량을 극대화 하고, 이산화탄소(CO2)을 생성하며, 작동의 안정성, 내구성, 분해 조립의 용이성 및 유지 보수성이 크게 향상되는 병해충 방제기용 산소원자 발생기 노즐에 관한 것이다. 본 발명은 절연체인 본체 및 상기 본체에 고정되는 망으로 구성되는 제1소켓과; 상기 제1소켓의 본체를 관통하여 전면 단부가 망 내부에 위치되는 방전핀과; 상기 제1소켓의 후면 방향으로 접속 결합되는 연결소켓과; 상기 연결소켓의 후면 방향으로 결합되는 제2소켓을 포함하여 구성하되,상기 연결소켓 및 제2소켓 사이에 한 개 이상의 차단벽을 형성하고, 상기 방전핀의 블레이드와 상기 망의 끝 부분에 형성되는 배출부 간의 거리가 상기 망의 외경 반지름보다 크게 하고, 상기 망의 배출구 직경은 망 외경 반지름보다 작게 하는 것을 특징으로 하는 병해충 방제기용 산소원자 발생기 노즐을 제공하기 위한 것이다. The present invention relates to an oxygen atom generator nozzle for a pest control device having a non-powered wind direction function, and more specifically, to maximize the amount of hydroxyl group (OH-) generated by stably and large amount of oxygen atoms, and carbon dioxide (CO2) It relates to an oxygen atom generator nozzle for a pest control device that produces and maintains stability of operation, durability, ease of disassembly and assembly, and maintainability. The present invention provides a first socket comprising a main body which is an insulator and a mesh fixed to the main body; a discharge pin penetrating through the body of the first socket and having a front end positioned inside the mesh; a connection socket connected and coupled in a rear direction of the first socket; and a second socket coupled in the rear direction of the connection socket, one or more blocking walls are formed between the connection socket and the second socket, and the blade of the discharge pin and the end of the net are formed To provide an oxygen atom generator nozzle for a pest control device, characterized in that the distance between the discharge parts is greater than the outer diameter radius of the net, and the outlet diameter of the net is smaller than the outer diameter radius of the net.

Gas supply system and gas supply method

Ozone generator

Ozone generator with depending on location discharge distribution

Изобретение относится к генератору озона и может быть использовано для дезинфекции воды или для отбеливания древесины, целлюлозы или пульпы для производства бумаги. Генератор озона содержит высоковольтный электрод (5) и по меньшей мере один контрэлектрод (1), ограничивающие промежуточное пространство, в котором установлен по меньшей мере один диэлектрик (2) и сквозь которое проходит газ в направлении спрямленного потока. Высоковольтный электрод (5) и по меньшей мере один контрэлектрод (1) имеют подключение электропитания (7) для производства тихих разрядов, исходящих из поверхностных точек. Центральное расстояние между высоковольтным электродом (5) и по меньшей мере одним контрэлектродом (1) и центральное разрядное расстояние неизменны. Количество поверхностных точек, из которых исходят тихие разряды, снижается в направлении спрямленного потока. Технический результат: повышение производительности за счет снижения электрической мощности, подаваемой в направлении газового потока на единицу поверхности электрода, причем генератор озона имеет максимально простую и экономичную конструкцию. 2 н. и 6 з.п. ф-лы, 2 ил. РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 663 744 C1 (51) МПК C01B 13/11 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ (52) СПК C01B 13/11 (2018.05); B01J 19/088 (2018.05); C02F 1/78 (2018.05); C01B 2201/14 (2018.05); C01B 2201/22 (2018.05); C01B 2201/64 (2018.05); C01B 2201/70 (2018.05) (21)(22) Заявка: 2017132079, 15.01.2016 15.01.2016 Дата регистрации: 09.08.2018 23.02.2015 DE 10 2015 002 102.8 (56) Список документов, цитированных в отчете о поиске: WO 9214677 A1, 03.09.1992. RU (45) Опубликовано: 09.08.2018 Бюл. № 22 94042390 A1, 27.07.1996. RU 2346886 C2, 20.02.2009. WO 9709268 A1, 13.03.1997. US 5554345 A1, 10.09.1996. US 5945072 A, 31.08.1999. (85) Дата начала рассмотрения заявки PCT на национальной фазе: 13.09.2017 (86) Заявка PCT: 2 6 6 3 7 4 4 (73) Патентообладатель(и): КСИЛЕМ АЙ ПИ МЕНЕДЖМЕНТ С.А Р ...

Light-proof electrode for producing ozone

FIELD: chemistry. SUBSTANCE: invention relates to a system of electrodes for ozone generator. System comprises tubular external electrode (1), which is concentrically and at a distance surrounds a tubular dielectric (2). Dielectric (2) surrounds rod (3) concentrically at a distance. Rod (3) is an insulator. In intermediate space between external electrode (1) and dielectric (2) there is filler (4). In intermediate space between dielectric (2) and rod (3) there is filler (5) in form of an internal electrode. EFFECT: technical outcome is effective prevention of short circuit at breakdown, high fault-tolerance, intrinsic safety, reduced weight and costs for materials. 8 cl, 2 dwg РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 590 540 C2 (51) МПК C01B 13/11 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ (21)(22) Заявка: ИЗОБРЕТЕНИЯ К ПАТЕНТУ 2013138444/05, 16.01.2012 (24) Дата начала отсчета срока действия патента: 16.01.2012 Приоритет(ы): (30) Конвенционный приоритет: (72) Автор(ы): ФИТЦЕК Райнер (DE), БИЛЛИНГ Эрнст Мартин (DE), ФИКЕНС Ральф (DE) 19.01.2011 DE 102011008947.0 (43) Дата публикации заявки: 27.02.2015 Бюл. № 6 R U (73) Патентообладатель(и): КСИЛЕМ АйПи ХОЛДИНГЗ ЛЛК (US) (45) Опубликовано: 10.07.2016 Бюл. № 19 (85) Дата начала рассмотрения заявки PCT на национальной фазе: 19.08.2013 2 5 9 0 5 4 0 (56) Список документов, цитированных в отчете о поиске: EP 0789666 B1, 13.10.1999. GB 1528731 A, 18.10.78. RU 94042390 A1, 27.07.1996. RU 2346886 C2, 20.02.2009. JPS 6451303 A, 27.02.1989. US 4035657 A, 12.07.1977. US 3967131 A, 29.06.1976. EP 2012/000153 (16.01.2012) C 2 C 2 (86) Заявка PCT: (87) Публикация заявки PCT: R U 2 5 9 0 5 4 0 WO 2012/097970 (26.07.2012) Адрес для переписки: 109012, Москва, ул. Ильинка, 5/2, ООО "Союзпатент" (54) ЛЕГКИЙ ИСКРОБЕЗОПАСНЫЙ ЭЛЕКТРОД ДЛЯ ПРОИЗВОДСТВА ОЗОНА (57) Реферат: Изобретение относится к системе электродов наполнитель (4). В промежуточном пространстве для генератора озона. Система содержит между ...

Ozone generating device

Изобретение относитс  к устройствам дл  получени  озона и может быть использовано в химической и фар ,мацевтической промышленности, в транспортном машиностроении и позвол ет повысить экономичность и упростить конструкции генератора озона за счет снижени  потребного давлени  питающего его сжатого газа вследствие уменьшени  необратимых потерь на трение в потоке. В генераторе озона имеетс  сопловой тангенциальный ввод 2 потока сжатого газа, диффузор 3 и заглушка 4, выполненные из диэлектрика и расположенные на противоположных сторонах корпуса,токо- провод щий торец 5 выхлопной щелевой части 6 диффузора, токопровод щий центральный стержень 7, установленный в заглушке 4. 2 ил. с The invention relates to devices for producing ozone and can be used in the chemical and headlamps, the processing industry, in transport engineering, and it allows to increase the efficiency and simplify the design of the ozone generator by reducing the required pressure of the compressed gas supplying it due to reducing irreversible friction losses in the flow. In the ozone generator there is a nozzle tangential inlet 2 of the compressed gas flow, a diffuser 3 and a plug 4 made of a dielectric and located on opposite sides of the body, a current-conducting end 5 of the exhaust slit part 6 of the diffuser, conductive central rod 7 installed in the plug 4 2 il. with

Ozonizer apparatus employing a multi-compartment bag for sterilizing

A sealed multi-chambered bag, that is a flexible container, is made of dielectric material and contains two electrode plates (preferably screen plates) that are separated by an internal wall of the bag. Materials to be sterilized are placed between one or the other or both of the electrode plates and the interior wall. The interior wall allows the plates to be contained within the bag without the risk of damaging high voltage discharges occurring between plates optimal ozone production occurs in the bag immediately adjacent to where the materials to be sterilized are located. The bag is placed within a chamber containing an aperture which is connected to the intake of a pump. A conductor connects each electrode plate to an opposed terminal of a high tension transformer. Both the pump and the transformer are connected to timing circuitry, which turns on the pump and the transformer and, then periodically turns the pump off and on to deflate and re-inflate the chambered bag and circulates the ozone produced therein to all virulence on the materials being sterilized. The gas within the bag alternatively expands and compresses before the transformer is turned off. The timer circuit allows the pump to continue to cycle on and off thereafter (preferably at an increased cycling rate) until the ozone off gas remaining in the bag is destroyed by molecular collision, surface reactions or otherwise.

Method for changing Line-erase in Plasma Display Panel &Apparatus therefor

본 발명은 화면의 각 비트의 라인 별로 발생하는 휘도 차이를 극복하기 위하여, 어드레스전극, 스캔전극 및 서스테인전극이 직교하는 부분에 셀이 형성된 패널에 입력 영상데이터에 따른 기록 전압, 스캔 전압, 서스테인 전압 및 라인소거 전압을 인가하여 화상을 표시하는 방법에 있어서, 입력 영상데이터를 비트 별로 분리하고, 비트 별로 분리한 각 비트의 영상데이터를 라인 단위로 가산하여 각 비트별 평균값을 산출하고, 각 비트별 평균값에 따라 각 라인의 상위비트와 하위비트들의 서스테인 방전을 소거할 위치를 각각 결정하고, 비트별 소거위치 데이터에 따라 라인 단위의 하위비트들은 복수의 라인과 동일한 위치에서 소거시키며, 상위비트에 해당되는 비트들은 각 비트 별로 소거위치를 가변시키며 단위 셀의 서스테인 방전을 소거함으로써, 휘도에 많은 영향을 미치는 상위비트들의 라인소거 위치를 부하량에 따라 가변할 수 있어 화면의 특정부위를 밝게 또는 어둡게 할 수 있을 뿐만 아니라 패널의 각 부분에 대한 휘도 차이를 극복할 수 있음과 아울러 화면의 부하에 따른 비정상적인 휘도 차이를 해소하여 보다 향상된 화질을 구현할 수 있는 플라즈마 디스플레이 패널의 라인 소거 방법 및 그 장치를 제공한다. According to the present invention, a write voltage, a scan voltage, and a sustain voltage according to input image data on a panel in which a cell is formed at a portion orthogonal to an address electrode, a scan electrode, and a sustain electrode in order to overcome a luminance difference occurring for each bit line of a screen. And a method of displaying an image by applying a line erasing voltage, wherein the input image data is separated bit by bit, and the image data of each bit separated by bit is added in line units to calculate an average value for each bit, and for each bit. The position of erasing the sustain discharge of the upper and lower bits of each line is determined according to the average value, and the lower bits of the line unit are erased at the same position as the plurality of lines according to the erase position data for each bit, corresponding to the upper bits. By changing the erase position for each bit and erasing the sustain discharge of the unit cell, The line erase position of the upper bits, which has a large influence on the figure, can be changed according to the load, so that not only the specific part of the screen can be brightened or darkened, but also the luminance difference of each part of the panel can be overcome, and The present invention provides a method and apparatus for erasing a line of a plasma display panel capable of ...

Ozone generator

本发明提供了一种能够以较少的电能消耗产生臭氧的小且轻的臭氧发生装置。本发明包括用于产生高压脉冲的脉冲发生器和用于响应高压脉冲而诱发放电的放电室。脉冲发生器包括用于压缩方波信号而产生脉冲的LC电路。脉冲的使用极大地减小了电能消耗和臭氧发生装置的体积。放电在电极板和接地的放电室壁之间发生。一层氧化物绝缘材料覆盖放电室壁，以防止放电室壁腐蚀。

Ozonater

본 고안은 오존 발생기에 관한 것이고, 원통형의 내부가 외주면 일측의 덮개(24)에 의해 폐쇄공간(23)을 형성하게 되며, 외주면에는 에어 유입부(21)가 형성되고, 축방향의 일측벽에는 오존 토출부(22)가, 그리고 타측벽에는 내주면에 나사부(31)가 형성되는 도체관(30)이 구비되는 부도체의 본체 케이스(20)와; 상기 본체 케이스(20)의 내부에 동일축방향으로 구비되고, 일단이 상기 오존 토출부(22)의 입구단에 연통되게 고정되며, 그 외주 둘레면에 도체 테이프(44)가 감싸지게 되는 파이프형의 석영관체(40)와; 상기 석영관체(40)내에 소정간격 이격상태를 유지하며 삽입되고, 그 단부가 상기 도체관(30)에 나사결합되는 파이프형의 방전체(60)와; 상기 본체 케이스(20)의 외주면 일측에 좌우 한 쌍으로 제공되되, 각각의 일단이 상기 도체 테이프(44)와 상기 도체관(30)의 외주둘레를 감싸며 그 타단들이 상기 본체 케이스(20)의 외주면 일측으로 노출되는 한 쌍의 전극 와이어(80)(90);를 포함하여 구성되는 것을 특징으로 한다. The present invention relates to an ozone generator, the inside of the cylindrical to form a closed space 23 by the cover 24 on one side of the outer peripheral surface, the air inlet 21 is formed on the outer peripheral surface, the one side wall in the axial direction A main body case 20 of the non-conductor having an ozone discharge portion 22 and a conductor tube 30 having a thread portion 31 formed on an inner circumferential surface thereof on the other side wall; It is provided in the same axial direction inside the main body case 20, one end is fixed to communicate with the inlet end of the ozone discharge portion 22, the pipe tape is wrapped around the outer peripheral peripheral surface 44 A quartz tube 40 of; A pipe-shaped discharge body (60) inserted into the quartz tube body (40) while keeping a predetermined interval therebetween, the end of which is screwed to the conductor tube (30); It is provided in a pair of left and right on one side of the outer circumferential surface of the main body case 20, each end of the outer peripheral surface of the conductor tape 44 and the conductive pipe 30 and the other end of the outer peripheral surface of the main body case 20 And a pair of electrode wires 80 and 90 exposed to one side.

High-efficiency and energy-saving ozone generator

本发明涉及环保技术领域，公开了一种高效节能臭氧发生器，包括：开关电源、DC/AC逆变器、升压单元和多个臭氧管，所述臭氧管包括：外管、内管、内电极和外电极，外管为陶瓷拉瓦尔管，内管为陶瓷柱管，外管在收缩段与扩张段连接处与内管之间的间隙为0.5～1.5mm，内电极伸入内管中，外电极固定在外管的外侧，外管上设有氧气入口和臭氧出口，内管上设有冷气入口和热气出口，升压单元的输出正极分别连接多个臭氧管的内电极，升压单元的输出负极分别连接多个臭氧管的外电极并接地，多个臭氧出口连通，连通处设有抽气装置，抽气装置与开关电源连接，这种臭氧发生器，提升了臭氧的生产效率，高效节能。

Ozone generating apparatus

PURPOSE: An ozone generating apparatus is provided to keep the amount of exhausting ozone constant by keeping the amount of air introduced into a discharging pipe constant. CONSTITUTION: An ozone generating apparatus includes a discharging pipe(10), a combining member(20), a first electrode part, and a second electrode part. The discharging pipe is made of a conductive material. One end part of the discharging pipe is inserted into the concave part of the combining member. The first electrode part is protruded from the bottom of the concave part to the discharging space of the discharging pipe. The second electrode part is contact with the outer circumference of the discharging pipe. One or more through holes are formed at the discharging pipe to introduce external air into the discharging space of the discharging pipe.

Electro-kinetic air transporter-conditioner

An electro-kinetic electro-static air conditioner includes a self-contained ion generator that provides electro-kinetically moved air with ions and safe amounts of ozone. The ion generator includes a high voltage pulse generator whose output pulses are coupled between first and second electrode arrays. Preferably the first array comprises one or more wire electrodes spaced staggeringly apart from a second array comprising hollow “U”-shaped electrodes. Preferably a ratio between effective area of an electrode in the second array compared to effective area of an electrode in the first array exceeds about 15:1 and preferably is about 20:1. An electric field produced by the high voltage pulses between the arrays produces an electrostatic flow of ionized air containing safe amounts of ozone. A bias electrode, electrically coupled to the second array electrodes, affects net polarity of ions generated. The outflow of ionized air and ozone is thus conditioned.

Air treatment apparatus having multiple downstream electrodes

An electro-kinetic air conditioner for removing particulates from the air creates an airflow using no moving parts. The conditioner includes an ion generator that has an electrode assembly including a first array of emitter electrodes, a second array of collector electrodes, and a high voltage generator. Preferably, a third or leading or focus electrode is located upstream of the first array of emitter electrodes, and/or a trailing electrode is located downstream of the second array of collector electrodes. The device can also include an interstitial electrode located between collector electrodes, an enhanced collector electrode with an integrally formed trailing end, and an enhanced emitter electrode with an enhanced length in order to increase emissivity.

Electro-kinetic air transporter and conditioner device with enhanced maintenance features and enhanced anti-microorganism capability

An electro-kinetic air conditioner for removing particulates from the air creates an airflow using no moving parts. The airflow is subjected to UV radiation from a germicidal lamp within the device. The conditioner includes an ion generator that has an electrode assembly including a first array of emitter electrodes, a second array of collector electrodes, and a high voltage generator. The device can also include a third or leading or focus electrode located upstream of the first array of emitter electrodes, and/or a trailing electrode located downstream of the second array of collector electrodes, and/or an interstitial electrode located between collector electrodes, and/or an enhanced emitter electrode with an enhanced length in order to increase emissivity.

Air conditioner device with removable driver electrodes

Embodiments of the present invention are directed to a method and apparatus for moving air using an air-conditioning system therein, whereby the air-conditioning system preferably includes at least one emitter electrode, at least one collector electrode, at least one driver electrode disposed adjacent to the collector electrode, and/or at least one trailing electrode positioned downstream of the collector electrode. The collector electrode and the driver electrode are removable from the device. In one embodiment, the driver electrodes are removable from the device and/or the collector electrode. The ability of remove the collector electrode as well as driver electrode allow for easy cleaning of the electrodes. In one embodiment, the present device includes a removable exhaust grill upon which the driver electrode and/or the trailing electrode are coupled to. The removable grill allows the user to easily clean the driver electrode without having to remove the collector electrode.

Ozone manufacture

Process for making ozone

A novel process and apparatus for synthesizing high-purity ozone (or for preparing test gas mixtures containing ozone). The process involves containing liquid nitrogen inside a vacuum dewar, supporting a dielectric ozonizer in the liquid nitrogen, evacuating the ozonizer to a low vacuum through a vacuum outlet, closing the vacuum outlet of the ozonizer, introducing highpurity oxygen into the ozonizer through an inlet, closing the inlet, applying a source of high-discharge alternating voltage across metal electrodes and oxygen therebetween, and removing the ozone thereby formed. The product is high-purity ozone. The apparatus comprises a two-walled annular ozonizer of Pyrex glass with electrodes secured onto the outer and inner surfaces.

Ozone generating lamp for preventing blacking

투명관과, 이 투명관의 양단에 설치되며 원통형의 메인전극과 메인전극 내부에 이격되어 설치되는 보조전극을 구비한 전극구조를 구비한 오존발생램프에 있어서, 원통형의 메인전극은 투명관의 양단으로부터 내측으로 진행됨에 따라 직경이 증가하는 오존발생램프가 개시된다. 메인전극의 외부표면으로부터 투명관으로 전달되는 빛이 없기 때문에 흑화현상을 방지할 수 있어 램프의 수명을 증가시키는 이점이 있다. In an ozone generating lamp having a transparent tube and an electrode structure having a cylindrical main electrode and an auxiliary electrode which is provided at both ends of the transparent tube and spaced apart inside the main electrode, the cylindrical main electrode has both ends of the transparent tube. An ozone generating lamp whose diameter increases as it proceeds from the inside to the inside is disclosed. Since there is no light transmitted from the outer surface of the main electrode to the transparent tube, it is possible to prevent blackening and increase the life of the lamp.