RU2457019C1 - Device to process air in electric discharge - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to air sanitisation in wards and other premises in the absence of or in the case of low-efficiency exhaust ventilation. Proposed device comprises rotor 1 with axial-blow fan impeller 7 fitted thereon. Moving electrode cylinder is arranged on impeller vane ends. Said electrode consists of inner current-conducting ring 8 and dielectric ring 7 arranged thereon to double as high-resistance barrier for moving electrodes. Device comprises also dielectric cylinder of stator 13. Blade electrodes 11, 12 are arranged in stator cutouts at acute angle to rotor tangent surface. Rotor has extra impeller 10 arranged nearby the end of moving electrode dielectric ring 9. Inner surface of stator 14 features cylindrical shape on extra impeller vanes to make flow-through section of axial-blow fan.

EFFECT: higher reliability and efficiency.

3 dwg

Description

The invention relates to devices that ensure the effect of an electric discharge on the flow of pumped air for the purpose of its bactericidal and chemical cleaning in hospital wards, residential premises, and also in the premises of penitentiary institutions in the absence or insufficient performance of exhaust ventilation.

A device of rotary type is known, intended for the action of non-equilibrium plasma excited in a unipolar barrier discharge on the flow of pumped air without exceeding the MPC for ozone (RF patent No. 2116244, MKI C01B 13/11 of July 27, 1998. Bull No. 21).

Here, an electric discharge gap is formed between the tip electrodes connected to the high voltage terminal of the unipolar voltage source and the dielectric barrier of the movable electrode mounted on the end face of the two-section centrifugal fan impeller. The removal of electric charges from the surface of the barrier of the movable electrode is carried out using grounded knife-type tip electrodes installed in the dielectric housing of the fan in alternating order with high-voltage electrodes and having the smallest possible gap with the surface of the movable electrode.

This system of electrodes forms an electric-discharge generator (ERG), which provides the excitation in air of atmospheric pressure of a stationary diffuse glow discharge in the gaps with high-voltage electrodes and a uniform surface discharge on grounded electrodes (Zhuravlev O.A., Ivchenko A.V., Strelnikov A.Yu. DC barrier corona with a potential electrode./ Abstracts of the XXXVI International (Zvenigorod) Conference on Plasma Physics and TCF. - M.: RFBR, 2009.- P.201). The homogeneity of the distribution of nonequilibrium plasma in the ERG sets the limits for regulating the processes of processing the air flow in the created ecological devices of the rotor type (Zhuravlev O.A., Ivchenko A.V. Unipolar plasma generators of the rotor type. / Collected proceedings of the Vth international symposium on theoretical and applied plasma chemistry.T.2. Ivanovo: IGHTU, 2008. - S.514-517).

Air treatment without exceeding the MPC for ozone is achieved by passing through the ERG a small part of the flow rate of the air pumped by the fan, followed by gas-dynamic mixing of the flows at the outlet of the device. The role of a gas-dynamic flow mixer is performed by a poorly streamlined body installed at the outlet of the fan duct, which turbulates the flow.

The disadvantage of this device is the instability of the operating modes of the ERG associated with the inconstancy of the discharge gaps between the tip (high-voltage and current collector) and the movable electrodes due to the vibrations of both the fan casing and the end of its rotor in the form of a two-section radial impeller.

Also, the device’s disadvantages include its large weight and size characteristics and insufficient operational safety associated with the combination of the fan and ERG functional units in one design, powered by mains (≈220 V) and high (10-12 kV) voltages.

Also known is a rotary type device for electric-discharge air treatment in small-sized enclosed volumes (RF patent No. 2173666, MKI C01B 13/11 of 09/20/2001. Bull. No. 26).

Here, the movable electrode-rotor, consisting of disks of the conductive screen and the dielectric barrier covering it, is mounted directly on the motor shaft. To ensure air pumping through the ERG, as well as to process it without exceeding the MPC for ozone, the disk of the dielectric barrier has periodic radial grooves extending at the periphery into the blades of the radial impeller of the centrifugal fan. The height of the impeller blades corresponds to the distance at which the inner surface of the dielectric flange of the generator housing is located with alternately mounted high-voltage and grounded electrodes.

A decrease in the ozone concentration in the ERG is achieved by mixing the treated and ozone-saturated air with the ambient air during the discharge extinction when passing under the high-voltage and grounded electrodes of radial grooves on the working surface of the movable electrode. The role of the intensifier of gas-dynamic mixing of flows is performed by window racks in the generator housing located at the outlet of the fan.

The disadvantages of the device include the presence of the danger of shorting the network power supply circuit of the electric motor and the high-voltage circuit of the ERG. In addition, the low performance of the fan leads to an increase in the time of circulation of air exchange inside the room to obtain an environment with a given level of ozone concentration.

It should also be noted that the presence of grooves on the working surface of the movable electrode and the associated regime of periodic extinction-excitation of the unipolar barrier corona increases the likelihood of sparking. This reduces the life of the dielectric substrate and creates the conditions for the generation of no less dangerous components in the air, such as nitrogen oxides.

A close technical solution that allows bactericidal and chemical treatment of air and prevents shorting of the network and high-voltage circuits of the fan and the ERG is a rotary device in the form of an electrostatic engine (A.S. No. 644020 USSR, M. Cl. Н02N 1/08 from 25.01. 79. Bull. No. 3).

The rotor of the electrostatic motor has a cylindrical shape and consists of an internal thin-walled conductive ring and an external dielectric ring covering it, playing the role of a high-resistance barrier of a movable electrode mounted on the ends of the blades of an axial fan impeller. The knife-type tip electrodes are installed in the through-cuts of the dielectric cylinder, which plays the role of a stator, and are oriented at an acute angle to the tangent surface of the circumference of the movable electrode. The angle of the electrodes lies in the range of 8-12 °.

The inner surface of the stator between the electrodes is made with bevels from the inner radius of the electrode to the outer one, which contributes to an increase in the volume of the treated gas. When a constant high voltage of alternating polarity is applied to the stator electrodes at their working edges, opposite corona discharges of the barrier type are excited, which ensure the transfer of the corresponding sign of charges to the surface of the movable electrode. The arising forces of the electrostatic interaction of the electrodes with the charges on the moving electrode lead to the rotation of the rotor with the inclusion of the axial fan and the ERG, which processes the air between the working surface of the moving electrode and the inner surface of the stator.

The absence of an air duct does not allow to regulate the process of mixing flows, makes it difficult to quantify the efficiency of air treatment.

The main disadvantage of the device is due to the instability of the discharge in the ERG due to the uncontrolled process of changing the sign of the charge structures on the moving electrode when passing under electrodes with opposite polarity. Recharging is a random process here. Its development is facilitated by the bipolarity of the applied high voltage source and the same gap between the working edge of the electrodes and the surface of the dielectric barrier. The loss of stability of the discharge and its spark shape lead to a decrease in the reliability of the device due to the growth of erosion processes on the surface of the dielectric barrier, a periodic decrease in the torque of the electrostatic forces of the engine, as well as local overheating of the air in the volume of the ERG with the possibility of producing nitrogen oxides in the formed ozone-air flow.

These disadvantages are eliminated in the prototype device for gas treatment in an electric discharge made on the basis of an electrostatic motor with a direct current barrier corona (AS No. 1756267 of the USSR, M. Cl. С01В 13/11 of 08/23/92. Bull. No. 31 )

The electrostatic motor of the device contains a rotor with an axial fan impeller mounted on the shaft and a movable electrode cylinder mounted on the ends of its blades, consisting of an internal conductive ring and a dielectric ring covering it, playing the role of a high-resistance electrode barrier. A perforated disk with an extended dielectric cylinder of the duct and a surface film-barrier with one-side metallization, creating a movable electrode of the main discharge gap of the device with a rod of a fixed high-voltage electrode installed in parallel, is installed on the same shaft.

Additional discharge gaps of the device are created in the electrostatic engine by knife electrodes placed in the slots of the stator dielectric cylinder, mounted at an acute angle to the tangent surface of the circumference of the corresponding movable electrode with the formation of an air gap.

The high-voltage electrode of the main discharge gap and the knife electrodes of the stator of the electrostatic motor are connected to a single unipolar high voltage source through the regulation resistors. In this case, the stator knife electrodes, being divided into high-voltage and grounded, are connected alternately to the high-voltage terminal of the voltage source, and the grounded electrodes have a minimum permissible gap relative to the surface of the movable electrode. The main and additional discharge gaps are housed in a single housing blown by an axial fan air stream in the form of an impeller fixed to the rotor shaft with blades located in the channel of the dielectric cylinder — the stator of the electrostatic motor.

The problem of gas-discharge treatment, which is solved here, of the entire air flow pumped through the housing without diluting it with a raw stream of untreated air, complicates the design of the device, increases the hydraulic resistance of the duct path, and narrows the scope due to the possibility of exceeding the MPC by ozone and nitrogen oxides in the outlet section of the housing.

The disadvantages of the electrostatic motor of the device include the low productivity of air treatment in the discharge gaps of the knife electrodes, due to the lack of forced gas flow through the gap between the working surface of the movable electrode and the inner surface of the stator. In addition, a perforated disk mounted on the rotor shaft with an extended dielectric cylinder of the duct has significant hydraulic resistance, which reduces the air flow rate of the axial fan.

The basis of the invention is the task of creating, on the basis of an electrostatic engine, a unified model of an electric-discharge generator-fan, which allows air to be processed without exceeding the MPC for ozone and nitrogen oxides in small-sized confined volumes while increasing the productivity of pumping air through the ERG and improving its mixing with the main gas stream, and also ensuring the stability of the discharge burning, which determines the level of reliability of the device as a whole.

This problem is solved due to the fact that in the device for processing air in an electric discharge containing a rotor, an impeller of an axial fan is fixed on its shaft, with a movable electrode cylinder, an internal conductive ring and a dielectric ring covering it playing the role of a high resistance the barrier of the movable electrode, as well as the dielectric cylinder of the stator, in the slots of which at a sharp angle to the tangent surface of the circumference of the rotor there is a row of knife electrodes , the rotor has an additional impeller located at the end of the dielectric ring of the movable electrode, while the inner surface of the stator is cylindrical in width of the impeller blades and forms the flow part of the peripheral axial fan.

The invention is illustrated by the drawing, presented in figure 1, which shows the inventive device; figure 2 shows a drawing of section aa in figure 1, and figure 3 shows an enlarged fragment B of the cross section of the flow part of the ERG with the blade of the peripheral axial fan.

A device for treating air in an electric discharge comprises a rotor shaft 1 mounted on two rolling bearings 2, which are located on two flanges 3, 4 with holes fixed at the lower ends in the base 5 and having a screed 6 in the upper part, which also acts as a handle for device transfer. An impeller 7 of an axial fan is mounted on the rotor shaft 1 with a movable electrode cylinder mounted on the ends of its blades, consisting of an internal thin-walled conductive ring 8 and an external dielectric ring 9. The rotor also includes an additional row of impeller blades 10 located at the end of the dielectric ring 9 of the movable electrode. The knife electrodes 11 and 12 are installed alternately in the through-cuts of the dielectric cylinder of the stator 13. They are oriented at an acute angle of 8-12 ° to the tangent surface of the circumference of the movable electrode and differ in the size of the gap with the surface of this electrode. The electrodes 11 having a gap h _B are high voltage, and alternating electrodes 12 with a gap h ₃ are grounded. The ratio of the sizes of the gaps meets the condition h _B = (5-6) h _Z. The gap h ₃ should not exceed 0.2-0.25 mm.

The dielectric cylinder of the stator 13 has two sections that differ in the profile of the inner surface. In the area with electrodes 11, 12, the inner surface of the stator 13 is made with bevels from the inner radius of the electrode to the outer, determining the geometry of the working chambers of the ERG, and in the area of the impeller 10, the inner surface of the stator has a cylindrical shape that limits the height of the impeller blades and forms a flow part of the peripheral axial a fan for pumping air through the ERG.

In addition, an impeller 14 of an additional axial fan is installed on the rotor shaft 1 in the area between the end face of the stator cylinder 13 and the output flange 4, at the ends of the blades of which there is a thin-walled dielectric cylinder-air duct 15 that overlaps the cylindrical part of the stator 13 with a guaranteed air gap h _P.

A device for processing air in an electric discharge works as follows. When a constant high voltage is applied to the electrodes 11 and the corona discharge ignition voltage is reached, the shaft 1, together with the impellers 7 and 14 of the rotor installed on it, starts to rotate. The rotation of the rotor occurs mainly due to the action of electrostatic repulsive forces between the high-voltage electrodes and the parts of the dielectric barrier 9 of the moving electrode with the same surface charge located in front of them in the gap h _{In the} sections of the dielectric barrier 9. An additional torque is created due to the action of electrostatic forces of attraction between the grounded electrodes 12 with the induced (induced) charge and the surface of the dielectric barrier passing below them in the gap h _З , transferring the surface charge of the same name with high-voltage electrodes 11. The induced gas discharge excited in the gaps h ₃ ensures uniform removal of the surface charge from the moving dielectric barrier. Also homogeneous combustion mode a discharge characteristic of a unipolar corona barrier type excited by the electrodes 11 in the gap h _B. Gas discharges realized in the claimed device do not lead to the initiation of uncontrolled spark processes of recharging the surface of the movable electrode, which is the basis for increasing the engine torque and the reliability of the installation without exceeding the MPC for ozone and nitrogen oxides.

The introduction of an additional impeller 10 into the rotor provides an increase in the productivity of air pumping through the ERG, and the installation of an additional axial fan with a dielectric cylinder-air duct 15 on the rotor rotor shaft 14 creates the conditions for efficient mixing of the treated gas with the pumped air flow without creating local zones in excess MPC level for ozone. In addition, the cylinder 15 of the duct, blocking the cylindrical part of the stator with knife electrodes, improves the safety of operation of the installation.

The values of the gaps h _P and h _Z are selected from the condition of the absence of contact between the corresponding moving and stationary structural elements of the device. The limitation on the gap value h _V is connected with the acceptability of the high voltage level of the device, which determines the operating conditions of the unipolar corona discharge both in the electrostatic drive of the fans and in the electric discharge generator of the air cleaner.

Claims (1)

A device for treating air in an electric discharge, containing a rotor, on the shaft of which an axial fan impeller is fixed, with a movable electrode cylinder mounted on the ends of its blades, consisting of an internal conductive ring and a dielectric ring covering it, playing the role of a high-resistance barrier of the movable electrode, as well as a dielectric a stator cylinder, in the slots of which at a sharp angle to the tangent surface of the circumference of the rotor there is a row of knife electrodes, characterized in that Op has the additional impeller being at the end face of the movable electrode of the dielectric ring, the inner surface of the stator on the width of the blades of the impeller further has a cylindrical shape and forms a part of the peripheral axial flow fan.

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