WO2018231102A1

WO2018231102A1 - Ion-plasma resonant ozone generator

Info

Publication number: WO2018231102A1
Application number: PCT/RU2018/000388
Authority: WO
Inventors: Дмитрий Николаевич ПОПОВ
Original assignee: Общество с ограниченной ответственностью "ИНВЕСТ ИНЖИНИРИНГ"
Priority date: 2017-06-13
Filing date: 2018-06-09
Publication date: 2018-12-20
Also published as: CN213623277U

Abstract

The utility model relates to devices for producing ozone, particularly to instruments that generate ozone by means of electric discharge. An ion-plasma resonant ozone generator includes a casing which contains a power supply unit, an ozone-generating electrode, an output transformer, an adjustment unit, a control unit, a phase discriminator, an amplitude detector, and a secondary signal winding of the transformer, the outputs of said winding being connected to the inputs of the phase discriminator and the amplitude detector. The output of the power supply unit is connected to the input of the adjustment unit, the output of which is connected to the windings of the transformer, which are connected to the ozone-generating electrode. The outputs of the phase discriminator and the amplitude detector are connected to the input of the control unit. The output of the control unit is connected to the input of the adjustment unit. The ozone-generating electrode is a pair of galvanically isolated conductors. Technical result: more efficient and stable ozone generation, increased reliability and longevity of the claimed device.

Description

Ion Plasma Resonant Ozone Generator

Utility Model Description

The inventive utility model relates to devices for the production of ozone, in particular to instruments using an electric discharge to generate ozone.

A known ozone concentration regulator (Patent SU 376762 published 04/05/1973) containing a gas flow regulator and a discharge power regulator connected to an ozonizer. The discharge power regulator comprises a current measuring transformer connected through an ozonizer current transducer to a potentiometer connected to an electric drive of an adjusting autotransformer connected to a transformer primary winding, the secondary winding of which is connected to an ozonizer.

The disadvantages of the known device are its low efficiency and stability of ozone generation, low reliability and durability of the device.

The closest analogue to the claimed ozone generator is a device for the production of ozone (Patent RU 1484 published 16.01.1996), containing an ozonizer connected to electric and gas power sources, and a device for measuring the amount of ozone. A device for measuring the amount of ozone includes a discharge current meter in the ozonizer.

The main disadvantages of the known analogue are also low efficiency and stability of ozone generation, low reliability and durability of the device.

The purpose of the claimed utility model is to eliminate the listed disadvantages to achieve such technical results as increasing the efficiency and stability of ozone generation, as well as increasing the reliability and durability of the claimed device.

The goal is achieved as follows: ion-plasma resonant ozone generator, comprising a housing that contains a power supply, an ozone-generating electrode, an output transformer and an adjustment unit; while the output of the power supply is connected to the input of the unit adjustment, the output of the adjustment unit is connected to the windings of the output transformer, which in turn are connected to the ozone generating electrode, and, furthermore, it contains a control unit, a phase discriminator, an amplitude detector and a secondary signal winding of the transformer, the terminals of which are connected to the inputs of the phase discriminator and the amplitude the detector, the outputs of the phase discriminator and the amplitude detector are connected to the input of the control unit, and the output of the control unit is connected to the input of the adjustment unit; Moreover, the ozone-generating electrode is a pair of galvanically unconnected conductors.

The ozone generator in particular can be characterized in that the casing is completely made of curable plastic.

The ozone generator in particular can be characterized in that the conductors of the ozone generating electrode are intertwined.

The ozone generator in particular may be characterized in that the conductors of the ozone generating electrode are insulated.

An ozone generator in particular may be characterized in that the terminals of the output transformer are provided with connectors in which an ozone generating electrode is fixed.

The ozone generator in particular may be characterized in that it is provided with a connector for connection to an external power source.

The ozone generator in particular may be characterized in that the power supply unit comprises an AC transformer source with a rectifier.

The ozone generator in particular may be characterized in that the power supply is a pulsed current source. The ozone generator in particular may be characterized in that the power supply comprises a direct current source using a battery.

The ozone generator in particular may be characterized in that it further comprises a voltage zero fixing unit, the input of which is connected to the power supply, and the output is connected to the input of the control unit.

The ozone generator in particular may be characterized in that the adjustment unit is assembled based on a field effect transistor.

The ozone generator in particular may be characterized in that the control unit further comprises a memory module.

In FIG. presents a block diagram of the inventive ion-plasma resonant ozone generator, where the numbers indicate the following:

1. Case

2. Power supply

3. Ozone generating electrode

4. Output transformer

5. Adjustment unit

6. The control unit

7. Phase discriminator

8. Amplitude detector

9. Secondary signal winding

10. Power Connector

11. Connectors for connecting the ozone-generating electrode

The ozone generator shown in the figure is arranged as follows.

The inventive device is assembled in a housing 1, which, in particular, can be completely made of a curable material (epoxy resin, compound or other similar plastic), a power connector 10 exits from the housing 1 for connection, for example, to an external main network,

s as well as connectors 11 for rigid connection of the ozone-generating electrode 3.

The generator includes a power supply 2 connected to the control unit 5, the output transformer 4 with, for example, two windings associated with a pair of conductors of the ozone-generating electrode 3; the combination of the above blocks constitutes the main circuit for the formation of ozone on the electrode 3, in which an oscillating circuit is formed on the basis of the output transformer 4 and the conductors of the electrode 3 galvanically disconnected from each other.

In addition, the generator also contains an additional control circuit, including a secondary signal winding of the transformer 9, a phase discriminator 7, an amplitude detector 8 and a control unit 6, which in turn is connected to the adjustment unit 5.

The ozone generator shown in the figure operates as follows.

External power supply (for example, from the mains network, from an external battery, etc.) is supplied through the connector 10 to the power supply unit 2. In this case, the power supply unit 2 may contain an AC transformer source with a rectifier, or a pulsed current source. A possible embodiment of the device with a power supply, which is a constant current source using a battery. The power supply converted by the power supply unit 2 to the required parameters, in particular direct current, is supplied to the input of the adjustment unit 5. The adjustment unit 5 (assembled, for example, based on a field-effect transistor) in this case controls the power supply parameters of the output transformer 4 supplied to the main windings . Each of the windings of the transformer 4 at the output, in turn, is connected to one of the conductors of the ozone-generating electrode 3. Moreover, the ozone-generating electrode is a pair of galvanically unconnected m I am waiting a conductor which, for example, may be intertwined and including, each enclosed in a separate isolation. It is in this way that the power supply of the electrode 3 is organized along the main circuit of the claimed device.

The basis for the formation of a stable electric discharge in the inventive device is an oscillatory circuit formed by a transformer 4 and, having capacitors, the conductors of the electrode 3. Between the conductors of the electrode 3 there arises in particular a barrier discharge (as an effective and economical source of ozone), which generates ozone into the environment.

However, during the operation of the ozone generator, environmental parameters such as humidity, temperature, density, and the concentration of oxygen in the surrounding air can change; which, undoubtedly, changes the parameters of the oscillatory circuit in particular, the value of the capacitance between the conductors of the ozone-generating electrode 3. Also, the capacitance of the oscillatory circuit may change with time the appearance of soot, dust, etc. on the conductors. Thus, the ozone generating ability of the device is reduced.

In order to adjust the concentration of generated ozone, a control circuit is introduced into the ozone generator, formed from a control unit 6, a phase discriminator 7 and an amplitude detector 8. This circuit operates as follows: from the secondary signal winding of the transformer 9, an electric signal is supplied to the phase discriminator 7, which allows track phase shift information during ozone generation. On the other hand, the amplitude detector 8, also included in the secondary signal winding of the transformer 9, transmits information about the amplitude changes. When changing the reactance parameters, which may vary from time to time due to the reasons listed above, information is processed to the control unit 6, which is processed and then, to the gate of the field-effect transistor located in the control unit 5, a control signal is received from the control unit 6. As a result, control unit 5 adjusts the output parameters so that resonance is maintained in the oscillating circuit. Maintaining resonance in the circuit not only ensures the stability of generation, but also keeps the level of ozone generation at a constantly high level.

Also, the ozone generator may further comprise a voltage zero fixing unit (not shown in FIG.), The input of which is connected to the power supply, and the output is connected to the input of the control unit. A zero fixing block (not shown in FIG.) Is used for greater accuracy of the control unit.

A memory module (not shown in Fig.) Can be enclosed inside the control unit, for example, for recording test parameters of the generator operating mode in the form of patterns and subsequent comparison of these patterns with the ones obtained control circuit data to increase accuracy and reliability of maintaining stable operating modes of the generator.

As a result of the use of the claimed utility model, firstly, the stability of the discharge and the maintenance of the concentration of generated ozone within the given limits are ensured; secondly, in addition, due to ensuring a uniform discharge on the electrode, the aggressive effect on its material is reduced, as a result of which the reliability of uptime of the device increases, and its service life increases.

Thus, the use of an ozone generator in the claimed configuration allows to achieve the claimed technical results, namely, increasing the efficiency and stability of ozone generation, as well as improving the reliability and durability of the claimed device.

Industrial applicability.

The inventive ion-plasma resonant ozone generator is manufactured at electronic enterprises from well-known widely distributed elements, and can be successfully applied both for domestic and industrial purposes, for example, when storing large masses of vegetables and other products in long-term storage warehouses.

Claims

Ion Plasma Resonant Ozone Generator

Utility Model Formula

A.1. An ion-plasma resonant ozone generator, including a housing that contains a power supply, an ozone-generating electrode, an output transformer and an adjustment unit; wherein the output of the power supply is connected to the input of the adjustment unit, the output of the adjustment unit is connected to the windings of the output transformer, which in turn are connected to an ozone-generating electrode, characterized in that it further comprises a control unit, a phase discriminator, an amplitude detector and a secondary signal winding of the transformer, outputs which are connected to the inputs of the phase discriminator and the amplitude detector, the outputs of the phase discriminator and the amplitude detector are connected to the input of the control unit, and the output of the control unit is connected to the input of the adjustment unit; Moreover, the ozone-generating electrode is a pair of galvanically unconnected conductors.

A.2 Ozone generator according to Claim 1, characterized in that the casing is completely made of curable plastic.

P.Z. The ozone generator according to claim 1, characterized in that the conductors of the ozone generating electrode are intertwined.

A.4. The ozone generator according to claim 1, characterized in that the conductors of the ozone-generating electrode are enclosed in insulation.

A.5. The ozone generator according to claim 1, characterized in that the outputs of the output transformer are equipped with connectors in which an ozone generating electrode is fixed.

A.6. The ozone generator according to claim 1, characterized in that it is equipped with a connector for connecting to an external power source.

A.7. The ozone generator according to claim 1, characterized in that the power supply unit contains an AC transformer source with a rectifier. Π. 8. The ozone generator according to claim 1, characterized in that the power supply is a pulsed current source.

A.9. The ozone generator according to claim 1, characterized in that the power supply contains a constant current source using a battery.

A.10. The ozone generator according to claim 1, characterized in that it further comprises a voltage zero fixing unit, the input of which is connected to the power supply, and the output is connected to the input of the control unit.

A.11. The ozone generator according to claim 1, characterized in that the control unit is assembled on the basis of a field effect transistor.

A.12. The ozone generator according to claim 1, characterized in that the control unit further comprises a memory module.