RU2116244C1 - Device for air deodoration and bactericidal treatment in electrical discharge - Google Patents

Abstract

FIELD: bactericidal and chemical treatment of atmospheric air in electrical discharge. SUBSTANCE: device has electric motor whose shaft mounts shank of radial-flow fan blading having two impellers joined together by means of end dielectric diaphragms. Blading is inserted in scroll case that has two side inlet holes (left- and right-hand ones) and common air duct that forms outlet air flow. Right-hand inlet hole is provided on wall that serves also to secure scroll case relative to motor shaft. Left-hand inlet hole has auxiliary lugs with two pairs of electrodes: needle-type high-voltage electrodes and blade-type current- collecting electrodes. Electrodes are mounted on metal studs threaded in upper part. Electrode pair is secured by means of auxiliary shank provided on disk in hole on fan impeller axle. High-voltage electrodes are connected to unipolar high-voltage source and have negative polarity; current-collecting electrodes are grounded. Left-hand inlet hole in fan receives air flow controller made in the form of movable bushing installed in auxiliary lug hole in case for longitudinal displacement and locking at desired distance a from electrode pair surface. Scroll case accommodates flow mixer mounted at outlet of air duct and incorporating poorly streamlined body with projecting plate. EFFECT: improved capacity and simplified design of device. 3 dwg

Description

 The invention relates to devices intended for the impact of an electric discharge on the flow of atmospheric air with the aim of its bactericidal and chemical cleaning, and can be used to normalize the air environment of medical and domestic premises.

 The variety of sources of harmful organic and inorganic compounds, the possibility of increasing the bactericidal activity of air in domestic and medical rooms require a practical assessment of both the well-known and widely used air purification systems, and the creation of new technical solutions.

 Currently known household over-air cleaners quite effectively clean the air of aerosol particles (dust, micro-droplets of oil), however, their possibilities when cleaning air from organic compounds are very limited. This is due to the fact that the adsorption treatment system (adsorbent - activated carbon) has a small resource, and regeneration of the adsorbent at home and in medical facilities is practically impossible.

 The bactericidal UV lamps used for air disinfection require constant monitoring of the cleanliness of the outer surface of the glass tube, they remain a danger of cracking the flask and contamination of the room with mercury vapor.

 Bactericidal lamps usually require evacuation of people from the room and purify the air in limited quantities.

 A device for air purification [1], containing a compartment of the ventilation channel with an electric discharge generator formed by a system of electrodes of a thread tube. The electrodes are placed inside the compartment in cross-directed groups in at least two parallel planes with the formation of a lattice. Tubular electrodes consist of a dielectric (quartz) tube with graphite filler. The electrode system is powered by a high voltage AC source operating at a frequency of 2-20 kHz. The air stream containing harmful ingredients, passing through the discharge zone, is exposed to the "active centers" generated in the discharge (UV radiation, atomic oxygen, ozone, electrons, etc.). At the same time, air is sterilized, and the molecules of toxic gaseous substances decompose (oxidize) into harmless components - water and carbon dioxide. The use of a pointed electrode made in the form of a thread led to a sharp decrease in aerodynamic drag for the gas-air flow in comparison with a system of barrier discharge electrodes. The inhomogeneous electric field of the discharge facilitated the contact of the entire mass of gas to be treated with the active region of the discharge. An increase in the air pumping rate made it possible to organize convective cooling of the electrodes.

 The main disadvantage of the device is associated with a high concentration of ozone at the output. This limits the scope of the device to uninhabited technologies (industrial channels). The expansion of the areas of operation of the device requires the introduction of catalysts to reduce the time of destruction of ozone at the exit. However, ozone catalytic afterburners have a complex manufacturing technology and a limited service life. Their use in air purifiers requires the introduction of a catalyst state monitoring system, which necessitates the disposal of spent catalysts. This complicates the design of the device, increases its cost. The next disadvantage is caused by the presence of a “barrier effect”, which is formed when alternating voltage is applied in the electrode system with a dielectric barrier and consists in the formation of an uncontrolled phase of the spark channel for discharging the dielectric during a change in the polarity of the electrodes. Overheating of air in the channel of the spark discharge leads to the production of secondary plasma-chemical products, reduces the reliability of the device.

 The elimination of these drawbacks is possible in electric-discharge devices, where the discharge excitation in the gap with the dielectric barrier does not require the use of a source of alternating voltage, and air treatment is carried out with a minimum concentration of ozone.

 The closest technical solution to the proposed device is a device for processing gas in an electric discharge [2], which contains fixed high-voltage and additional grounded electrodes and a movable grounded electrode with a dielectric barrier, enclosed in a case with a single air duct, connected to a unipolar source of high constant voltage with impeller axial fan driven by an electrostatic motor. The use of a high-voltage unipolar source in the power circuit of the device eliminated the "barrier effect", which led to a decrease in the amount of nitrogen oxides or a side carcinogenic substance in the output stream below the maximum permissible concentration.

 The disadvantages of the device are associated with a small radius of curvature of the working edge of the high-voltage electrode, made in the form of a rod. This limits the level of attainable electric field strengths E in the discharge gap and reduces the efficiency of the conversion processes for air purification. A high rate of chemical reactions of oxidation of ionized and dissociated impurity molecules, water and oxygen is achieved in air, when the maximum electron energy distribution in the discharge is 6-7 eV. This corresponds to electric fields in the air of the order of E = 100 - 150 kV / cm and can be achieved only in the streamer corona burning on the tip or needle electrode. Another disadvantage of the device lies in the design of the air duct, where an axial fan is used, leading to the formation of a single air flow. The air flow completely passes through the electric discharge gap, which is formed on the output section of the air duct between the generatrix of the movable electrode, made in the form of a cylindrical rotor, and a rod high-voltage electrode located parallel to it. The passage of all processed gas through the interelectrode gap leads to saturation of air with ozone, and the placement of the discharge gap at the outlet of the air duct makes it difficult to use gas dynamic mixers, which make it possible to reduce the concentration of ozone at the outlet of the device by diluting it in the untreated air stream. The use of an electrostatic engine in the device complicated the design of the air duct and led to an increase in the geometric dimensions of the air cleaner.

 The basis of the invention is the task to simplify the design and reduce the geometric dimensions of the device, to increase the productivity of air processing without exceeding the maximum permissible concentration (MAC) of ozone at the outlet.

 The solution to this problem is achieved due to the fact that the device for deodorization and bactericidal treatment of air in an electric discharge contains fixed high-voltage and additional grounded electrodes and a movable electrode with a dielectric barrier enclosed in a cochlea with a single air duct and connected to a unipolar source of constant high voltage combined with the impeller of a radial fan. According to the invention, the fan impeller has two impellers connected with end dielectric diaphragms with side inlets in the housing-cochlea. Moreover, one of the inlets contains an air flow regulator made in the form of a movable sleeve, and a gas-dynamic flow mixer is located at the outlet of the air duct.

 Fixed high-voltage needle-type electrodes and grounded knife-type electrodes are installed in pairs with the same pitch in the technological tides of the housing around the perimeter of the inlet with the sleeve. The electrodes have the possibility of axial movement and are oriented perpendicular to the surface of the movable electrode, which is made in the form of a flat disk lying on the end diaphragm of the corresponding impeller, and is fixed with a technological shank in the hole on the impeller axis.

 A gas-dynamic flow mixer is installed at the outlet of the air duct of the housing-cochlea from the side of the impeller wheel with movable and fixed electrodes and contains a poorly streamlined body with a protruding plate having a sawtooth profile on the working edge.

 A general view of the device is shown in FIG. one; in FIG. 2 shows a section AA in FIG. one; in FIG. 3 shows a view B in FIG. 1, section BB and view G.

 The device has an electric motor, on the shaft 1 (Fig. 2) of which the shank 2 of the radial fan impeller is fitted, having two impellers connected by end dielectric diaphragms. The impeller is inserted into the housing-cochlea 3, which has two lateral inlet openings (left and right, Fig. 2) and a single air duct (Fig. 1), which forms the output stream. The right inlet is located in the wall 4, which is also used for fastening the housing-coils 3 relative to the shaft 1 of the motor. The left inlet of the housing 3 has technological tides that contain two pairs of electrodes 5 and 6, 5 are high-voltage needle-type electrodes, and 6 are knife-type collector electrodes. The electrodes 5 are made in the form of metal studs having threads on the upper part. The electrodes 6 are mounted on the studs 7, also having a threaded part. The threads on the studs 5 and 7 are used to fasten the insulating caps 8 and allows you to adjust the installation height of the electrodes 5 and 6 relative to the surface of the movable electrode (PE), including a flat metal disk 9 with a surface dielectric film 10. PE using a technological shank on the disk 9 is fixed in holes in the shank 2 on the axis of the wheel of the fan impeller. The electrodes 5 are connected to a unipolar high voltage source 11 and have a negative polarity, and the electrodes 6 through the studs 7 are grounded. The left inlet to the fan has an air flow regulator 12, made in the form of a movable sleeve mounted in the hole of the technological tide in the housing 3 with the possibility of longitudinal movement and fixing at a given distance a relative to the plane of PE.

 At the outlet of the air duct in the housing-cochle 3 (Fig. 3), a flow mixer is installed in the form of a poorly streamlined body 13 with a plate 14 having a sawtooth profile of height h on the working edge (Fig. 3). Elements 13 and 14 overlap the output section at a width of ≤ 0.5b (see Fig. 3) from the side of the impeller with an electric discharge generator (ERG) formed by electrodes 5 and 6 in the air gap with a movable electrode 9, 10.

 A device for processing air works as follows.

After turning on the electric motor and achieving the operating mode of rotation of the fan impeller, a single turbulized gas stream is formed at the outlet of the air duct of the cochlear casing 3, which is formed of two parts differing in the level of flow rate. Low flow rate is ≈ 0.1 part of the main one and is set by the flow regulator 12, which blocks the cross section in the left inlet to the fan by changing the distance a from the lower edge of the sleeve to the PE plane. In addition, the flow regulator 12 provides the removal of pumped air to the PE plane, creating conditions for the passage of low flow through the interelectrode gaps 5-PE, 5-6 ERG. When a constant high voltage U ≥ U _{s is} applied from the source 11 to the electrodes 5 of the ERG, where U _s is the discharge ignition voltage in a low-flow air stream, a unipolar barrier discharge is excited in the intervals of the 5-PE generator, accompanied by an induction discharge in the PE-6 gap. When high U increases at the electrodes 5 and U ≃ (2-3) U _of the discharge in the gap 5 PE-lit mode in the streamer corona, and on the surface between the electrodes 5 and 6 is raised a further gas discharge - homogenous surface discharge. In this case, the poorly streamlined body 13 forms in front of itself a stagnant zone with a vortex recirculation flow, where the ozone concentration was ≤ 6 MPC according to the measurement results. The plate 14 with a sawtooth profile of the working edge provides turbulization of the output stream, creating conditions for ejection input into the main air stream of the low-flow part. The scale of the turbulent formations and the degree of dilution of ozone in the output stream are determined by the height h of the teeth on the plate 14. As shown by measurements, already at h = 5 mm the concentration of ozone in the stream at a distance of ≈ 10 cm below the outlet section from the air duct decreased to the MPC level for household appliances (60 mcg / m ³ ). In this case, the microbial contamination of the pumped air at the outlet of the device was below the background level in the room from 1.6 to 3 times.

 The deodorization capabilities of the device were determined by the degree of decrease in the concentration of impurities in the air stream behind the fan with the ERG high voltage source turned off and on. Measurements showed that when the ERG is turned on, the device reduces the concentration of phenol, formaldehyde and propane molecules in the stream by 5-10 times. When the ERG was turned off, the concentration of molecules of these impurities decreased in the flow by more than 2 times.

Claims (3)

 1. Device for deodorization and bactericidal treatment of air in an electric discharge, comprising a housing with a single air duct and an input side hole, fixed high-voltage electrode and knife-type electrodes and a movable electrode with a dielectric barrier, combined with a fan impeller, characterized in that the radial fan impeller has two impellers connected by end dielectric diaphragms, while coaxially with the inlet on the opposite side of the housing a second inlet, wherein the air flow regulator is mounted in a movable sleeve, and the output of the air-flow channel disposed mixer, wherein a fixed high voltage electrode is connected to the needle and unipolar high voltage DC source, and knife-type electrodes are grounded.  2. The device according to claim 1, characterized in that it is equipped with an additional stationary high-voltage electrode, and the high-voltage electrodes and grounded electrodes of knife type are installed in pairs with the same pitch in technological tides around the perimeter of the inlet with the sleeve, have the possibility of axial movement and are oriented perpendicular to the surface a movable electrode, which is made in the form of a flat disk coaxial with the impeller, lying on the end dielectric diaphragm in the corresponding input hole the impeller and secured with a technological shank in the hole on the axis of the impeller.  3. The device according to claims 1 and 2, characterized in that at the outlet of the air duct in the cochlea case a flow mixer is installed in the form of a poorly streamlined body with a protruding plate having a sawtooth profile on the working edge.

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