RU2184076C1 - Discharge chamber of ozonizer - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: discharge chamber has coaxial electrodes and dielectric barrier, and discharge initiators located in annular grooves formed in electrodes and adjoining to dielectric barrier arranged in spaced relation to electrodes to define discharge gaps. Discharge chamber of such construction provides for wide range of ozone concentration at ozonizer outlet end. EFFECT: increased efficiency and wider range of usage. 4 cl, 4 dwg, 1 tbl

Description

 The invention relates to the production of ozone in an electric discharge and can be used in medicine (therapy, dermatology, dentistry, surgery, etc.).

 Ozonizers based on electric discharge are widely used in medicine for the production of an ozone-oxygen mixture, since with pulsed feeding they allow the production of ozone in a wide range of concentrations and provide the possibility of implementing strictly dose-dependent individual ozone therapy.

 A known discharge chamber of an ozonizer containing coaxial electrodes and a dielectric barrier mounted between them (RU 2063928 C1, 07.20.1996).

 In the known discharge chamber, the dielectric barrier is positioned with a gap with respect to the external electrode and is adjacent to the internal electrode made of sheet brass. Under the influence of high voltage voltage pulses in the interelectrode gap, an electric (barrier) discharge is excited. At the same time, in micro-gaps formed due to a loose contact of the surface of the sheet electrode with the dielectric barrier, a discharge is also ignited, which causes an increase in temperature, reducing the reliability of the device and the performance in ozone. In addition, the linear shape of the discharge gap leads to inefficient use of the volume of the discharge chamber.

 Closest to the claimed is the discharge chamber of the ozonizer containing coaxial electrodes and a dielectric barrier (RU 2118939 C1, 09.20.1998).

 In the discharge chamber of the prototype, the inner electrode is formed by a finely divided metal filler placed in a dielectric capsule. In addition, an additional coaxial electrode adjacent to the inner surface of the dielectric tube divides the working volume of the chamber into two parts with the formation of a labyrinth system, including external and internal discharge gaps. Oxygen-containing gas sequentially passes through the discharge gaps, which increases the utilization rate of the working volume of the discharge chamber.

 The disadvantage of the discharge chamber is that when an independent barrier discharge is formed, due to the absence of initiation elements, the time delay of the discharge ignition time increases. This reduces the discharge and discharge current carried during the power pulse. As a result, discharge power and ozone productivity are reduced. The delay and the low stability of the moment of ignition of the discharge are especially large in the region of low repetition frequencies of the power pulses. For example, at a repetition rate of less than 20 Hz, the gas gap breaks through during the maximum voltage at the electrodes, and breakdown does not occur at all in individual pulses, which reduces the reliability of the known device when it is used in ozonizers with a dynamic range of more than two orders of magnitude.

 In addition, dielectric barriers are located in an inhomogeneous thermal field, since there is a temperature gradient and mechanical stresses between the surface facing the discharge gap and the surface pressed against the electrode, which leads to a decrease in the strength of the barriers and the reliability of the device. Moreover, at the boundary between the barriers and the electrodes, in closed gas cavities, a discharge also burns, which leads to overheating of the reactor zone and, as a result, a limitation of the frequency of supply of voltage pulses, a decrease in productivity, and an increase in the linear discharges of the discharge chamber.

 The objective of the invention is the creation of a small-sized device that provides a wide range from 10 μg / l to 12000 μg / l of a range of concentrations of ozone at the outlet of the ozonizer.

 The technical result in solving this problem is to increase the reliability and productivity of ozone while reducing the size of the device.

 The indicated technical result is achieved in that the ozonizer discharge chamber containing coaxial electrodes and a dielectric barrier further comprises discharge initiators located in the circular grooves made in the electrodes and adjacent to the dielectric barrier located with gaps with respect to the electrodes to form discharge gaps. In addition, the initiators of the discharge are made in the form of at least one pair of coil springs closed in a ring, the first spring being installed in the annular groove of the inner electrode and adjacent to the inner surface of the dielectric barrier, and the second spring located above it installed in the annular groove of the external electrode and adjacent to the outer surface of the dielectric barrier. The initiators of the discharge can also be made in the form of corrugated foil strips enclosed in a ring or in the form of foil strips enclosed in a ring with a needle surface facing the dielectric barrier.

 Under the action of high-voltage voltage pulses applied to coaxial electrodes, an increase in the electric field intensity occurs in the discharge gaps. Moreover, in the region of initiators opposite each other on opposite sides of the dielectric barrier, there is a local increase in the electric field strength and the appearance of the first microdischarges here. The ultraviolet radiation they produce irradiates the working volume of the gas and the surface of the electrodes, initiating the development of a barrier discharge in the entire interelectrode gap. The greatest force of the electric field is observed in areas close to the places where the initiators come in contact with the dielectric barrier. The accelerated development of discharges in areas with maximum field strength causes a decrease in the ignition voltage of the discharge and ensures the formation of a barrier discharge at the time of the maximum rate of increase in voltage in the gas gap. As a result, the transferred charge during the pulse and the average active current per unit time increase, which increases the intensity of plasma-chemical processes and productivity.

 The implementation of the initiating elements with the touch of the dielectric barrier provides the opportunity, from the point of view of effective generation of ozone, of timing the timing of the ignition of the discharge in each voltage pulse when the frequency changes from fractions of Hz to units of kHz, which increases the reliability of the discharge chamber in wide-range ozonizers.

 The small area of the working sections of the initiators of the discharge allows you to transfer through them only a small part of the total charge, which increases the durability of the initiators and the reliability of the device.

 Ring grooves provide the location of the initiators at a given minimum distance relative to each other, as well as the tight contact of the initiators with the surface of the electrodes, increasing the reliability of the structure during mechanical stresses arising during transportation and operation.

 The location of the dielectric barrier with a gap between the two electrodes increases the cooling efficiency of the most loaded parts of the electrode system, which are the internal electrode and the areas where the initiators of the discharge adjoin the dielectric barrier, which reduces the temperature in the reactor zone, decreasing the part of the discharge power spent on ozone decomposition, and increasing productivity with smaller dimensions compared to the prototype.

 In addition, the gas stream flows around the inner and outer surfaces of the dielectric barrier in opposite directions. As a result, the thermal field gradients and mechanical stresses in the dielectric barrier are reduced, which increases the reliability of the claimed device.

 Figure 1 shows the inventive discharge chamber. Figure 2 shows a section aa with the initiators of the discharge, made in the form of cylindrical springs closed in a ring. Figure 3 presents a section aa in the case of discharge initiators made in the form of corrugated foil strips closed in a ring. In FIG. Figure 4 shows section AA in the embodiment of the initiators in the form of foil strips closed in a ring with a needle surface facing the dielectric barrier.

In the figures used the following notation:
O ₂ is oxygen, O ₃ is ozone. The arrows indicate the direction of gas flow.

 The discharge chamber of the ozonizer contains coaxial electrodes 1.2 and a dielectric barrier 3, placed with a gap relative to the electrodes 1.2 with the formation of discharge gaps (figure 1). In addition, the device includes at least one pair of initiators of the discharge 4,5, which can be performed in several versions: in the form of cylindrical springs closed in a ring (figure 2), or corrugated foil strips (figure 3), or foil strips with a needle surface (Fig. 4) facing the dielectric barrier 3. In this case, the initiator 4 is installed in the annular groove of the inner electrode 1 and is adjacent to the inner surface of the dielectric barrier 3, and the initiator 5 located above it is installed in the annular groove of external electrode 2 and is adjacent to the outer surface of the dielectric barrier 3.

 In an example implementation of the proposed device, the inner electrode 1 was provided with holes 6 for uniform distribution of the oxygen flow in the discharge gap and holes 7 for the output of the ozone-oxygen mixture (Fig. 1). In order to increase the cooling efficiency, the outer surface of the electrode 2 was ribbed. The discharge chamber also included a supporting insulator 8, made in the form of a gas distributor with an oxygen flow supply pipe 9, a bushing 10 and a high-voltage insulator 11. In the supporting insulator 8, the left parts of the electrodes 1.2 and the dielectric barrier 3 were installed, and a bushing was secured in the bushing 10 the right side of the electric barrier 3, in the high-voltage insulator 11 the right parts of the electrodes 1,2 were attached.

 Coaxial electrodes 1.2 were made of duralumin, dielectric barrier 3 was made of a quartz tube, initiators of discharge 4.5 were made of nickel alloy, support 8, passage 10, and high voltage 11 insulators were made of fluoroplastic.

 The device operates as follows.

 The electrodes of the 1.2-bit chamber are connected to a generator of high-voltage pulses of alternating polarity. The inlet and outlet openings of the chamber are connected to the corresponding gas lines and the required gas flow is established. The power source is turned on and the required power is set (generator frequency). The resulting ozone-oxygen mixture is supplied to consumers.

 In the process, the initial oxygen flow is supplied into the internal cavity of the electrode 1 through the pipe 9, which flows out through the openings 6 radially located in it and into the internal discharge gap, spreads toward the supporting insulator 8, through the channels radially made in it, enters the external discharge gap, and then to the outlet holes 7 in the upper part of the electrode 1 (figure 1). Under the action of high-voltage pulses in the region of the initiators of the discharge 4,5, located opposite each other on opposite sides of the dielectric barrier 3, there is a significant, in relation to the surrounding space, an increase in the electric field strength. The microdischarges arising here produce plasma and ultraviolet radiation, which initiate the formation of a barrier discharge at the front of each voltage pulse, thereby providing the possibility of effective and stable production of ozone in a wide frequency range. Ring grooves provide a predetermined location of the initiators, as well as their electrical and thermal contact with the electrodes. A gas stream passing through the discharge gaps flows around both surfaces of the inner electrode, the dielectric barrier, contributing to efficient cooling of the reactor zone, which allows to increase the discharge power and productivity with smaller dimensions of the discharge chamber.

 The inventive discharge chamber containing two pairs of discharge initiators (Fig. 1) was tested as part of a medical ozonizer. The power source provided quasi-sinusoidal voltage pulses with an amplitude of 12 kV and a frequency from 1 Hz to 1400 Hz on the electrodes. Tests have shown that initiation ensured the formation of a discharge in each pulse at both high and (which is especially important) at low frequencies, increasing the reliability of the ozonizer. Breakdown of gas gaps occurred at the front of a voltage pulse. The breakdown time is quite rigidly fixed, its time spread was equal to ± 200 nanoseconds, the value of the breakdown voltage varied within 4-6 kV. The output ozone concentration was 10-12000 μg / L with an accuracy of ± 10% at a flow rate of 1 L / min.

 The table shows the characteristics of ozonizers with the proposed and known discharge chamber in the maximum power consumption mode.

 From their comparison it follows that an increase in the output concentration of ozone by almost three times is achieved by increasing the productivity of the discharge chamber.

 Thus, the invention allows to solve the problem of obtaining output concentrations of ozone in the range from 10 μg / l to 12000 μg / l while reducing the dimensions of the discharge chamber by increasing reliability and productivity by providing effective initiation of a barrier discharge and the location of the dielectric barrier with a gap relative to the electrodes.

Claims (4)

 1. A discharge chamber of an ozonizer containing coaxial electrodes and a dielectric barrier, characterized in that it further comprises discharge initiators located in the circular grooves made in the electrodes and adjacent to the dielectric barrier located with gaps with respect to the electrodes to form discharge gaps.  2. The discharge chamber of the ozonizer according to claim 1, characterized in that the initiators of the discharge are made in the form of at least one pair of coil springs closed in a ring, the first spring being installed in the annular groove of the inner electrode and adjacent to the inner surface of the dielectric barrier, and the second spring located above it is installed in the annular groove of the external electrode and is adjacent to the outer surface of the dielectric barrier.  3. The discharge chamber of the ozonizer according to claim 1 or 2, characterized in that the initiators of the discharge are made in the form of corrugated foil strips enclosed in a ring.  4. The discharge chamber of the ozonizer according to claim 1 or 2, characterized in that the initiators of the discharge are made in the form of foil strips closed in a ring with a needle surface facing the dielectric barrier.

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