RU2310138C2 - Method for supply of electroozonizer - Google Patents

Abstract

FIELD: supply of electroozonizer.

SUBSTANCE: the method consists in supply of electric power from an electric power source via a frequency converter and a step-up transformer to the discharge chamber and the fan electric motor, the electric power from the step-up tuned transformer in the resonance operating condition is transmitted from the high-voltage lead of its high-voltage winding through the first single-wire line to the input of the high-voltage matching device, rectified and fed to the corona-forming and coaxial electrodes of the discharge chamber, and from the low-voltage lead of the high-voltage winding the electric power is supplied through the second single-wire line to the input of the low-voltage matching device, rectified and fed to the fan electric motor, the third zero lead of the high-voltage winding of the tuned transformer discharge chamber and the electric motor are connected to the earth.

EFFECT: reduced loss of power, reduced specific quantity of metal and enhanced reliability of installation operation.

2 cl, 2 dwg

Description

The invention relates to methods and power supplies for electrical installations for generating ozone from air using an electric discharge and can be used in agriculture, food and chemical industries for disinfection, antiseptics, cleaning and deodorization of air in livestock buildings and during storage of agricultural products.

Being a strong oxidizing agent, ozone has high disinfecting and antiseptic properties with sufficient concentration in a mixture with air. The principle of operation of ozonizers and aeroionizers is based on the excitation and ionization of neutral molecules and air atoms in an inhomogeneous electric field of high tension due to corona discharge.

A known method of powering an electrical installation for antisepticizing agricultural products with an ozone-air mixture generated in the zone of a corona high-voltage electrode receiving a high voltage from a high-voltage transformer connected to the mains through counter-switched diodes and a switch, and a low voltage for supplying the electric motor of the grating conveyor is supplied directly from network.

The disadvantage of this method is the increased energy loss in the magnetic circuit of a high-voltage transformer and wires supplying a 2 ^x -4 ^x- core cable to drive a trellised conveyor to move the product, increasing the metal consumption and reducing the reliability of the electrical installation (see AS USSR No. 459210 in cl. A23L 3/32, BI No. 5, 1975)

A known method of supplying electrical installations for air purification in electrostatic precipitators at poultry complexes with a corona electrode system receiving a high voltage from a high-voltage transformer using an intermediate frequency and rectifying high-frequency voltage according to a half-wave multiplication scheme. The power supply of the electric-zoned electrical installation with a high-voltage circuit and the electric fan drive for supplying air is carried out directly via a four-wire power supply network.

The disadvantage of this method of supplying an ionizing electrical installation is a large energy loss in the magnetic circuit of a high-voltage transformer and supply wires, as well as high sensitivity to voltage increase, which can lead to a short circuit due to an increase in the corona current density and breakdown of the interelectrode space. The voltage multipliers installed at the output of the high-voltage transformer lead to a sharp increase in energy losses with an increase in the output power of the high-voltage power supply of ozonizers, and also have low reliability (see the book "The use of electromagnetic fields in agricultural processes." - Chelyabinsk, 1976. Authors: Vozmilov A.G., Taimanov S.T., article “High-voltage source for powering electrostatic precipitators”, p.95-100).

There is a method of supplying a flowing ionizer-ozonizer for the synthesis of ozone and negative aero ions, including supplying electricity from a source to a high-voltage transformer connected to a corona electrode of a discharge chamber, blown by air using a fan, the electric motor of which is powered from the source through a four-wire cable.

The disadvantage of this power supply method is a large energy loss in a closed magnetic circuit of a high-voltage transformer and in connecting wires, increased metal consumption associated with the need to lay a two- or four-wire electric cable to the electric insulator, as well as uneven distribution of the corona current in the discharge gap, which reduces the performance of the electric zoned installation. Another drawback in the power supply of the electric shielding is the possibility of a short circuit in the supply connecting wires (see, for example, the book: Krivopishin I.P. "Ozone in industrial poultry farming." M., Rosagropromizdat, 1988, pp. 16-32).

The objective of the invention is to provide a method for powering an electric shielding device, which reduces energy losses in a closed magnetic circuit of a high-voltage transformer and supply wires, eliminates short circuits in the power line, increases the uniformity of the distribution of the corona current of the discharge gap, reduces metal consumption and increases the reliability of the installation.

As a result of the use of the invention, energy losses, metal consumption of the device are reduced, the efficiency of the installation is increased.

The above result is achieved in that in a method for supplying an electric shielding device, including supplying electric energy from an electric energy source through a frequency converter and a step-up transformer to a discharge chamber and a fan motor, electric energy is transferred from a step-up high-frequency resonant transformer in resonance mode from the high-voltage output of its high-voltage winding via the first single-wire line to the input of the high-voltage matching device is rectified and fed to BID and coaxial electrodes of the discharge chamber and from the low voltage output of high-voltage winding of electrical energy for the second single line is transmitted to the input of low voltage matching device, rectified and fed to the fan motor, wherein the third zero output resonant transformer high voltage winding, a discharge chamber and a motor connected to ground.

In the method of supplying an electric shielding, the power of each of several discharge chambers is carried out by one conductor from one high-voltage output of the high-voltage winding of the boost resonant transformer through matching devices.

The power supply method of the electric shielding device is illustrated in FIGS. 1 and 2, where FIG. 1 is a flow diagram of a power supply method for the electric shielding device; figure 2 is a power supply circuit of an electric shielder with several discharge chambers and one fan.

The flowchart of the method for power supply of the electric shielding device, shown in Fig. 1, contains a power supply 1, a frequency converter 2, capacitances 3 connected to a low-voltage winding 4 of a high-frequency resonant transformer 5 having an open ferrite core 6. High-voltage winding 7 of a high-frequency resonant transformer 5 its high-voltage output 8 is connected by a first single-wire line 9 to the input of a high-voltage matching device 10 connected to a corona 11 and a coaxial 12 elec by delivery from the discharge chamber 13, and the low-voltage terminal 14, the high-voltage winding 7 is connected by a second single-wire line 15 to the input of the low-voltage matching device 16 connected to the fan motor 17. The discharge chamber 13 and the fan motor 17 are connected to the ground via matching devices 10 and 16. The third zero terminal 18 of the high voltage winding 7 of the boosting high frequency resonant transformer 5 is also connected to ground.

When using a branched duct 19 with several discharge chambers 13 in the electric shielding device (Fig. 2), each of them is connected via a high-voltage matching device 10 with a single-wire line 9 with one high-voltage output 8 of a high-voltage winding 7 of a step-up high-frequency resonant transformer 5, and also connected to ground.

The method, figure 1, is implemented as follows.

Electric energy from the power source 1 is supplied through a frequency converter 2 and a capacitance 3 to a low-voltage winding 4 of a step-up high-frequency resonant transformer 5, forming a resonant oscillatory circuit in a serial electric circuit. The high-voltage winding 7 of the step-up high-frequency resonant transformer 5 is connected by a high-voltage terminal 8 to the first single-wire line 9 with a high-voltage matching device 10 for rectifying and supplying high-voltage electric energy to the corona electrodes 11 of the discharge chamber 13, which carries out air ionization and ozone synthesis.

The high-voltage winding 7 of the step-up high-frequency resonant transformer 5 is connected by a low-voltage terminal 14 to the second single-wire line 15 with a low-voltage matching device 16 for rectifying and supplying electric energy of the corresponding voltage to the fan motor 17, blowing air through the working chamber of the electric deflector.

When implementing the method of supplying an electric shielder having several discharge chambers (Fig. 2), each discharge chamber 13 is powered by one conductor 9 from one high-voltage output 8 of the high-voltage winding 7 of the boost resonant transformer 5 through matching devices 10. The resonator mode of the generator-line system -load ”is created by changing the frequency of the current of the frequency converter.

An important advantage of the proposed method for powering the high-voltage circuit of the ozonizer is its high reliability. Even when the corona discharge passes into an electric arc, an emergency mode does not occur, the device remains operational and when the arc fails, it again switches to the nominal operating mode. The absence of a voltage multiplier significantly increases the reliability of the electric gap, and the use of a high-frequency resonant open-core resonant transformer dramatically reduces the energy loss in the magnetic circuit. Connection to a step-up high-frequency resonant transformer of an electric shielding or a group of electric shieldings on a single conductor reduces metal consumption and eliminates the possibility of a short circuit between the wires of the supply lines and wires.

The proposed method for supplying an electric shielding increases the efficiency of air treatment both due to the amount of ozone produced, and due to strong ultraviolet radiation in the working interval, which creates additional conditions for electronic and ion bombardment of air molecules while reducing energy consumption for ozone production.

The ecological purity of ozone and the availability of its production directly at the place of use using the proposed method of power supply of the electrozonator makes it possible to widely use ozone-ion technologies in agricultural production and food industry enterprises. Thanks to the air treatment of livestock buildings with an aero-ozone mixture using electrozonators, the content of harmful impurities (ammonia, hydrogen sulfide, carbon dioxide) and microorganisms in the air is significantly reduced. Such air treatment is very effective for creating and maintaining the necessary microclimate in livestock and poultry facilities.

Claims (2)

1. A method of supplying an electric shielding device, comprising supplying electric energy from a source of electric energy through a frequency converter and raising a transformer to a discharge chamber and a fan motor, characterized in that the electric energy from the raising high-frequency resonant transformer in resonance mode is transmitted from the high-voltage output of its high-voltage winding in the first a single-wire line to the input of the high-voltage matching device is rectified and fed to corona and coaxial the electrodes of the discharge chamber and the low voltage output of high voltage winding for electric energy of the second single line is transmitted to the input of the matching device of low-voltage, rectified and fed to the fan motor, wherein the third zero output resonant transformer high voltage winding, a discharge chamber and a motor connected to ground. 2. The method of power supply of the electric shielder according to claim 1, characterized in that the power of each of several discharge chambers is carried out by one conductor from one high-voltage output of the high-voltage winding of the boost resonant transformer through matching devices.

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