RU123605U1 - DEVICE FOR IMPLEMENTING METHOD FOR POWER SUPPLY OF DISCHARGE ASYMMETRIC OZONE GENERATOR - Google Patents

Abstract

1. A device for implementing the method of power supply of a discharge asymmetric ozone generator, containing a constant voltage source, the positive terminal of which is connected to the electrode of the ozone generator, covered with a dielectric layer, through a controlled valve with an antiparallel diode, and a choke, and the negative terminal of the constant voltage source is connected to the second electrode of the ozone generator, which does not have a dielectric layer, and the second controlled valve with a second anti-parallel diode, connecting the common junction point of the controlled valve and the choke with the negative terminal of the constant voltage source. The device for implementing the method of power supply of the discharge asymmetric ozone generator according to claim 1, characterized in that the ozone generator is included in the electrical circuit of the device through a transformer. The device for implementing the method of power supply of the discharge asymmetric ozone generator according to claim 2, characterized in that the primary winding of the transformer is connected to the electrical circuit of the device through a capacitor.

Description

The utility model relates to electrical engineering and can be used in the design of power sources for high-performance ozone generators, as well as various control systems for plasma-chemical processing of materials and products. The utility model is aimed at reducing energy consumption in the synthesis of ozone or plasma-chemical processing.

Discharge asymmetric ozone generators are the most common type of devices, including high power ones. These are, first of all, Welsbach generators, mass-produced by many domestic and foreign companies (Ozonation equipment. Catalog of Ozonia LLC 2010 / Ozonia Ltd, 2010, C.4; Ozonation equipment. Catalog of Kurgankhimmash 2012 / Kurganhimmash 2012, P.11; Silkin EM Synthesis of ozone in electric discharges and increase of its efficiency // KIT. - 2008. - No. 6. - S.136 - 143). In these devices, a barrier discharge is realized. The Welsbach ozone generator is “asymmetric”, since one of its electrodes is coated with a dielectric layer, and the other is an uncoated metal part (electrode). Asymmetric ozone generators also include a device with a high-voltage electrode in the form of a grid (P. 49813 of the Russian Federation, MKI C01B 13/11. Ozonator / E.M. Silkin. - Claim. 06/18/2005. - Publish. 10.12.2005. - Bull. No. 34).

The inventive device can be used to power other types of discharge generators, for example, operating on the principles of corona or spark discharge.

A device for implementing a method for powering a discharge asymmetric ozone generator, containing a constant voltage source, the terminals of which are connected via a choke, a single-phase bridge on controlled valves and a transformer with a primary winding shunted by a capacitor, with ozone generator electrodes (P. 2020710 RF, MKI N02M 5 / 45. A frequency converter with a DC link / E.M. Silkin et al. - Declaration of December 23, 1992. - Publish of September 30, 1994. - Bull. No. 18).

The disadvantage of the device for implementing the method of powering a discharge asymmetric ozone generator is the high energy consumption in the synthesis of ozone, which is due to the consumption of energy from a constant voltage source with positive and negative current through the generator electrodes. When a negative current flows (an electrode without a dielectric coating is an anode), ozone is practically not synthesized in the discharge gap. The energy consumed, equal to the energy consumed during the flow of a positive current (the electrode with a dielectric coating is the anode), is not spent on synthesis, but only on heating the parts of the discharge gap. Increased heating leads to the decomposition of already synthesized (with a positive current) ozone, which reduces its output from the discharge zone.

A device for implementing a method for powering a discharge asymmetric ozone generator containing a constant voltage source, the terminals of which are connected through a single-phase bridge on controlled gates with counter-parallel diodes and a transformer with electrodes of an ozone generator (P. 2159497 RF, MKI N02M 5/44. Control method frequency converter / E.M. Silkin. - Application. 04/13/1999. - Publish. 11/20/2000. - Bull. No. 32).

The disadvantage of this device for implementing the method of powering a discharge asymmetric ozone generator is the high energy consumption in the synthesis of ozone, which is due to the consumption of energy from a constant voltage source at positive and negative current through the generator electrodes. When a negative current flows (an electrode without a dielectric coating is an anode), ozone is practically not synthesized in the discharge gap. The energy consumed, equal to the energy consumed during the flow of a positive current (the electrode with a dielectric coating is the anode), is not spent on synthesis, but only on heating the parts of the discharge gap. Increased heating leads to the decomposition of already synthesized (with a positive current) ozone, which reduces its output from the discharge zone.

A device is known for implementing a method for powering a discharge asymmetric ozone generator containing a constant voltage source, the terminals of which are connected through a single-phase bridge on controlled gates with counter-parallel diodes, a choke and a transformer with electrodes of the ozone generator (P. 2155432 RF, MKI N02M 5/45. Frequency converter / E.M. Silkin. - Application. 04/13/1999. - Publish. 08/27/2000. - Bull. No. 24).

The specified device is the closest in technical essence to a utility model and is selected as a prototype.

The disadvantage of the device for implementing the method of powering a discharge asymmetric ozone generator is the high energy consumption in the synthesis of ozone, which is due to the consumption of energy from a constant voltage source with positive and negative current through the generator electrodes. When a negative current flows (an electrode without a dielectric coating is an anode), ozone is practically not synthesized in the discharge gap. The energy consumed, equal to the energy consumed during the flow of a positive current (the electrode with a dielectric coating is the anode), is not spent on synthesis, but only on heating the parts of the discharge gap. Increased heating leads to the decomposition of already synthesized (with a positive current) ozone, which reduces its output from the discharge zone.

The utility model is aimed at solving the problem of reducing energy consumption for ozone synthesis, which is the purpose of the utility model.

The specified goal is achieved by the fact that:

1. The device for implementing the method of powering a discharge asymmetric ozone generator, contains a constant voltage source, the positive output of which is connected to the ozone generator electrode coated with a dielectric layer, through a controllable valve with an anti-parallel diode and a choke, and the negative terminal of the constant voltage source is connected to the second the electrode of the ozone generator, which does not have a dielectric layer, and a second controlled valve with a second counter-parallel diode, connecting a common ku compound managed throttle valve and with the negative side DC voltage source;

2. A device for implementing the method of powering a discharge asymmetric ozone generator according to claim 1, characterized in that the ozone generator is included in the electrical circuit of the device through a transformer;

3. The device for implementing the method of powering a discharge asymmetric ozone generator according to claim 2, characterized in that the primary winding of the transformer is included in the electrical circuit of the device through a capacitor.

A significant difference characterizing the utility model is the reduction of energy consumption for ozone synthesis, which is caused by the absence of energy consumption from a constant voltage source at a negative current through the ozone generator electrodes (an electrode without a dielectric layer is an anode, that is, it has a positive potential), and a decrease in heating of the dielectric layer and other parts of the discharge gap and, therefore, a decrease in the degree of decomposition of already synthesized ozone. As a result, ozone output increases with a general decrease in energy consumption, therefore, energy consumption also decreases.

The reduction in energy consumption for ozone synthesis is a technical result due to the new principles of the zone power supply by the quasi-pulse voltage, the features of the new design and new elements in the electrical circuit of the device, lowering the temperature of the parts of the discharge gap, that is, the hallmarks of the utility model. Thus, the distinguishing features of the claimed device for implementing the method of power supply of a discharge asymmetric ozone generator are essential.

Figure 1-3 shows variants of the circuits of the device, figure 4 presents time diagrams (t-time) of the voltage u and current i of the ozone generator.

A device for implementing the method of powering a discharge asymmetric ozone generator, contains a constant voltage source 1, the positive output of which is connected to the electrode of the ozone generator 2, coated with a dielectric layer, through a controlled valve 3 with an on-parallel diode 4 and a choke 5, and a negative output of a constant voltage source connected to the second electrode of the ozone generator, which does not have a dielectric layer, and a second controlled valve 6 with a second counter-parallel diode 7, connecting th connection point managed throttle valve and with the negative side DC voltage source. The ozone generator can be included in the electrical circuit of the device through the transformer 8. In this case, the primary winding of the transformer can be included in the electrical circuit of the device through the capacitor 9.

A device for implementing the method of powering a discharge asymmetric ozone generator in steady state operates as follows. The ozone generator 2, as an element of an electric circuit, is a container. At zero voltage on the ozone generator 2, the supply of control pulses (pulse) to the valve 3 is allowed, which is carried out by the control system of the device (not shown). The controlled valve 3 (Fig. 1) is turned on and the increasing current i in the circuit begins to flow: 1-3-5-2-1. The upper (according to the scheme) electrode of the ozone generator 2 with a dielectric layer, when valve 3 is turned on, acts as an anode, and the lower electrode is a cathode. Since the ozone generator 2 has a capacity, the current i in the circuit (due to the operation of the inductor 5) changes exponentially (Fig. 4). Choke 5 limits the slew rate of current i. The capacity of the ozone generator 2 is charged and the voltage u increases on the ozone generator 2. When the instantaneous value of current i reaches the set maximum (positive) value of I, valve 3 turns off. Due to the energy stored in the electromagnetic field of the inductor 5, the current i continues to flow in the positive direction along the circuit: 5-2-7-5. In this case, the current i decreases, and the voltage u continues to increase. As soon as the energy of the field of the inductor 5 is used up, the current i in the circuit will stop, the voltage u on the capacity of the ozone generator 2 will stop increasing, and the diode 7 will turn off. If the voltage u becomes sufficient to ignite the barrier discharge in the discharge gap of the ozone generator 2, the discharge will light up and ozone synthesis will begin. Ozone is synthesized on the surface of the dielectric layer of the electrode of ozone generator 2. A new control pulse is supplied to valve 3, and it turns on. The voltage u on the capacitance of the ozone generator 2 is directed opposite to the voltage of the source 1, therefore, the instantaneous current i in the circuit: 1-3-5-2-1 to the maximum value of I increases over a longer time interval. Qualitatively, electromagnetic processes are repeated. When the voltage reaches the maximum set value of U, the supply of control pulses to valve 3 is prohibited, and it turns off. The interval of positive current i passing through the electrodes of ozone generator 2 ends. The number of starts of the controlled valve 3 in this interval depends on the set values of the maximum forward current I and the maximum voltage U, as well as the magnitude of the inductance of the inductor 5. In particular, the capacity of the ozone generator 2 to the maximum voltage U can be produced in one turn on of the controlled valve 3 . It is allowed to supply control pulses to the second valve 6. In the interval of negative current i (the electrode with the dielectric layer is the cathode), the constant voltage source 1 does not give off energy . All processes occur due to the energy stored in the electric field of the capacity of the ozone generator 2. The negative current i flows along the circuit: 2-5-6-2 and increases exponentially to the set maximum value J. Next, the controlled valve 6 is turned off, and the current i continues to flow in the negative direction (decreasing in magnitude) in the circuit: 5-4-1-2-5 due to the energy stored in the electromagnetic field of the inductor 5. The voltage u on the capacitance of the ozone generator 2 continues to decrease. As soon as the energy of the field of the inductor 5 is used up, the current i in the circuit will stop, the voltage u at the capacity of the ozone generator 2 will stop decreasing, and the diode 4 will turn off. If the voltage u drops below a certain value, a discharge will light up in the discharge gap of the ozone generator 2. In this case, ozone is practically not formed, but the energy from the constant voltage source 1 is not consumed. Part of the reactive energy of the inductor 5 is recovered to source 1 (during operation of the counter-parallel diode 4). The controlled valve 6 is periodically turned on until the capacity of the ozone generator 2 is completely discharged. When the voltage u at the capacity of the ozone generator 2 decreases to zero, the supply of control pulses to the valve 6 is prohibited and the supply of control pulses to the valve 3 is allowed. Further, the processes in the device circuit are cyclically repeated. As in the case of a positive current, the discharge of the capacitance of the ozone generator 2 by negative current can be carried out in one pulse.

As controlled valves 3, 6, transistors or lockable thyristors can be used in the device. It is possible to use analogues of two-operation valves made on conventional thyristors.

To align the device with the load (ozone generator 2) according to the voltage level, in order to optimize energy consumption, the ozone generator 2 can be included in the electrical circuit through a transformer 8 (figure 2). The transformer 8 must be designed to operate with a frequency of voltage change and on the capacity of the ozone generator 2. The inductor 5 when using a transformer 8 can be excluded from the circuit. In this case, instead of the inductance of the inductor 5, the leakage inductance of the transformer 8 is used.

Fundamentally, the inductor 5 can be excluded in the circuit shown in figure 1. Its inductance is replaced by the busbar inductance of the device.

To exclude the possible operation of the transformer 8 on the private hysteresis loop and reduce the magnetization reversal losses, the primary winding of the transformer 8 can be connected in series with the capacitor 9 (Fig. 3). If the capacity of the capacitor 9 significantly exceeds the capacity of the ozone generator 2, the specified capacitor 9 practically does not distort the electromagnetic processes in the circuit. Throttle 5 can also be omitted here.

The operation of devices made according to the schemes of FIGS. 2, 3 occurs similarly to the operation of the device shown in FIG. 1.

Compared with the prototype, the total energy consumption for the synthesis of ozone in the barrier discharge can be reduced by 1.7-2 times. In the interval of negative current flowing through the electrodes of the ozone generator, in which there is no ozone synthesis, no energy is also consumed from the power source. Reducing energy losses due to heating of the dielectric layer, ceteris paribus, almost doubled the output of ozone.

Compared with the prototype, in addition, the power part of the device is greatly simplified and its cost is reduced. The reliability of the device and the load (ozone generator) increases. The maximum concentration of ozone in the working gas mixture can be increased.

Compared with the prototype, in addition, due to the above advantages, the scope of application of the new device for implementing the method of power supply of a discharge asymmetric ozone generator is expanding.

Claims (3)

1. A device for implementing a method of powering a discharge asymmetric ozone generator, containing a constant voltage source, the positive output of which is connected to the ozone generator electrode coated with a dielectric layer, through a controllable valve with an anti-parallel diode, and a choke, and the negative terminal of the constant voltage source is connected to the second electrode of the ozone generator, which does not have a dielectric layer, and a second controlled valve with a second counter-parallel diode, connecting a common the connection point of the controlled valve and inductor with a negative terminal of a constant voltage source. 2. A device for implementing the method of powering a discharge asymmetric ozone generator according to claim 1, characterized in that the ozone generator is included in the electrical circuit of the device through a transformer. 3. A device for implementing the method of powering a discharge asymmetric ozone generator according to claim 2, characterized in that the primary winding of the transformer is included in the electrical circuit of the device through a capacitor.