RU72409U1 - AIR IONIZER - Google Patents

Abstract

The utility model relates to devices for generating electronegative oxygen-containing ions from atmospheric air and can be used in medicine, veterinary medicine, crop production, animal husbandry and other biotechnologies, in particular, it can be used for anti-stress rooms, hospital (rehabilitation) rooms, operating rooms, emergency rooms, dressing rooms and burn centers, in ozone therapy, as well as in other recovery rooms. High efficiency of the air ionizer is ensured by the implementation of the electrodes and their placement inside the body of the air ionizer. The electrodes are mounted on metal rings. The cathode is made in the form of a grid, and the anode is made in the form of a grid, with rods fixed to it perpendicular to the grid plane, staggered with a step equal to its height, the entire surface of the grid and rods, except for the vertices of the latter, is covered with a dielectric film, the electrodes are installed inside the housing so that the distance from the fan to the anode is greater than the distance from the fan to the cathode by an interelectrode distance that is not less than twice the height of the rod. The distance between the electrodes is fixed by a dielectric insert made in the form of a hollow cylinder. This embodiment of the electrodes and their placement provides an air stream at the outlet of the discharge gap with the advantage of electronegative oxygen-containing ions of neutral nitrogen and an insignificant concentration of free radicals in the form of OH groups.

Description

The utility model relates to devices for generating electronegative oxygen-containing ions from atmospheric air and can be used in medicine, veterinary medicine, crop production, animal husbandry and other biotechnologies, in particular, it can be used for anti-stress rooms, hospital (rehabilitation) rooms, operating rooms, emergency rooms, dressing rooms and burn centers, in ozone therapy, as well as in other recovery rooms.

Air ionizers, including Chizhevsky's chandeliers, are very widely used in medicine, cosmetology and in everyday life. However, these devices, designed to generate electronegative ions, along with negative ions produce a whole gamut of both positive ions and neutral radicals. Since nitrogen is the main component in atmospheric air, there are more than three times more positive ions in the supplied air than electronegative ones.

The presence in residential or workrooms of a very high concentration of electropositive ions and free radicals (especially at high humidity) adversely affects biological objects, as it reduces the body's reaction, slowing down the conversion of O ₂ ⇔CO ₂ during breathing due to a decrease in the concentration of dissolved CO ₂ in blood, and reducing the ATP produced during this transition with significant dehydration of the interstitial zone.

As a prototype of the utility model, an air ionizer was adopted, containing a cylindrical body with an inlet fan installed, a needle electrode placed along the body axis, and a grid, the electrodes connected to opposite poles of a high-voltage regulated constant current source, the grid overlapping the cross section of the housing located on a larger distance from the entrance than the needle electrode, and with the latter creates an inhomogeneous electric field, the ratio of the length and diameter of the input section of the confuser and the inner the diameter of the cylindrical body lies in the range of 0.1-0.5 and 1.0-1.66; the ratio of the distances of the needle tip and mesh

from the input end of the confuser to the inner diameter of the casing are in the range of 1-1.5 and 1.5-2.0, respectively, the total length of the cylindrical casing with the confuser is 2.8-3.3 of the inner diameter of the casing. In the air ionizer, when opposite potentials are supplied to the needle electrode and the grid, an inhomogeneous electric field appears between them, which acts on the air entering through the confuser, which leads to the appearance of a large number of aero ions, which, under the action of electrostatic forces, move in the direction of the output end and create a unidirectional flow creating ventilation effect (RU 2132974, F04D 33/00, 07/10/99).

A disadvantage of the known air ionizer is the low efficiency of the device due to the presence at its output of a significant concentration of positive ions and neutral radicals.

The technical result of the utility model is to increase the efficiency of the device by preventing the appearance of positive ions at its output and significantly reducing the concentration of neutral radicals.

The technical result of the utility model is achieved by the fact that in the air ionizer containing a cylindrical body with a fan installed on the input end and two electrodes placed inside the body that perform the functions of a cathode and anode and connected to a power source, the cathode is made in the form of a grid, the anode is made in the form mesh, with rods fixed to it perpendicular to the mesh plane, staggered with a step equal to its height, and the entire surface of the mesh and rods, except for the vertices of the latter, is covered and with a dielectric film, the electrodes are installed inside the case so that the distance from the fan to the anode is greater than the distance from the fan to the cathode by an interelectrode distance that is not less than two times the height of the rod, and a high-voltage generator is used as a power source pulses of the nanosecond range.

The rod of the electrode performing the function of the anode can be made in the form of a needle.

The pulse repetition rate of the high-voltage pulse generator of the nanosecond range is chosen close to the resonant frequency of the intermolecular bond of the molecules of the source to air ionization.

The pulse amplitude of the high-voltage pulse generator of the nanosecond range is not less than twice the magnitude of the voltage at which the ionization process occurs.

The cylindrical body is made of dielectric material.

An air ionizer with the above set of features allows you to get an air stream at the outlet with the advantage of electronegative oxygen-containing ions, neutral nitrogen and an insignificant concentration of free radicals in the form of OH groups.

The drawing (Fig. 1) shows an example of the proposed air ionizer. Figs. 2 and 3 conditionally illustrate the formation of a sharply inhomogeneous electric field between the electrodes.

The air ionizer contains a fan 1 mounted on the inlet end of the cylindrical body 2, inside which two electrodes (4 and 6) are placed, which respectively act as a cathode and anode, an electrode 4 (cathode) is mounted on a metal ring 3, and an electrode 6 (anode) is fixed on a metal ring 5, the electrodes are connected to a high-voltage pulse generator of the nanosecond range (not shown in the drawing). The cathode 4 is made in the form of a grid, and the anode 6 is made in the form of a grid, with rods 9 fixed to it perpendicular to the grid plane, staggered with a step equal to its height (h), the entire surface of the grid and rods, except for the vertices of the latter, is covered with a dielectric film, the electrodes (4, 6) are installed inside the housing 2 in such a way that the distance from the fan 1 to the anode 6 is greater than the distance from the fan 1 to the cathode 4 by the interelectrode distance “a”, which is not less than two times the height (h) of the rod. The distance between the electrodes is fixed by a dielectric insert 8 made in the form of a hollow cylinder.

The operation of the device is as follows.

The fan 1, which can be used as a typical low-power fan, is rigidly fixed to the end of the housing 2, made in

a pipe made of dielectric material. This fan drives atmospheric air through a discharge device consisting of two mesh electrodes 4 and 6, mounted on metal rings 3 and 5. respectively. The electrode 4, which is the cathode, is located closer to the fan 1. The negative polarity pulses from the output of the high-voltage generator are applied to the electrode 4 pulses of the nanosecond range. To connect this electrode 4 to the output of the high-voltage pulse generator of the nanosecond range, a typical connector 7 or other contact device can be used. A high voltage nanosecond pulse generator must generate pulses of duration t = 300 ns and a front duration of τ _fr ≤100 ns. The electrode 6, relative to which the supply of high-voltage pulses is carried out, is grounded, i.e. its potential is zero. The electrode 6 is placed inside the housing 2 so that the rods fixed on the grid of the electrode 4 are directed towards the electrode 4 (cathode). The value of the interelectrode distance “a” should be at least two times the height of the rod, and the amplitude of the pulses of the high-voltage pulse generator of the nanosecond range should be at least two times the magnitude of the voltage at which the ionization process occurs (the voltage of the “ignition” of the corona). The grid of the electrode 6 together with the rods 9 fixed to it is covered, in addition to the very top of the rod, with a dielectric film with a thickness of at least 170 μm, because starting from this value, the required uniformity of the coating is ensured, and, therefore, the integrity and uniformity of the screen. When high-voltage pulses are applied to electrodes 4 and 6, a sharply inhomogeneous electric field is formed between them, a conditional illustration of which is shown in Figs. 2 and 3. This field will be electrostatic before the onset of corona discharge and calculated analytically with a given accuracy.

From Figs. 2 and 3 it follows that when a pulse voltage u (t) is applied to the electrodes, the value of which is less than the corona ignition voltage Ui, the field between the electrodes 4 and 6 is purely electrostatic with variable height height and has gaps in the zones between the rods 9 (needles). If u (t)> Ui and up to its amplitude value around the top of the rod (needle)

ionization occurs, characterized by anodized streamers, the trajectories of which resemble a spray jet with a characteristic zone near the apex, with the properties of a low-temperature plasma. From the top of this zone, which depends on the overvoltage relative to the ignition of the corona, towards the electrode 4 (cathode) (in fact, from the entire interelectrode space towards the tip of the needle), there are many streamers at the same time. An area with plasma properties has a bright glow with a weighted average radiation length λ≈400 ÷ 460 nm, and a region with simultaneously existing streamers has a bright blue glow (ultraviolet) in the range 110≤λ≤300 nm. Simultaneously with the removal of the space charge into the discharge gap, an electric wind arises, the speed of which is proportional to the square of the discharge current and is directed (velocity plot) along the field lines of force.

The air supplied to the device by the fan 1 passes through the mesh electrode 4, is converted due to the forces of the electric field and contact with its surface (two grids), as a result of which ions and free radicals are formed. The chemical composition of both ions and radicals depends on the composition and humidity of the source air. Once in the interelectrode space, the final separation of ions occurs in sign, mass and acquired speed. Positive ions from nitrogen and its oxides to heavy metals freely moving in the zone of weak electric field strength without noticeable resistance (due to the action of the transport velocity υ1), driven by the electric wind, rush to the huge surface of the cathode, where they are neutralized. Negative ions (just oxygen-containing) rush to the anode, adjusted by the flow at a speed of υ ₁ and braked by the electric wind. As a result of this complex effect, defocusing in the movement of negative ions occurs. Only negative ions transported only along the central power line (see FIG. 3) can be neutralized, settling and discharging on a small surface of the tip. Negative ions deposited on the lateral surface of the rods 9 (needles) focus the flow, which consists mainly of electronegative ions, increasing their speed of movement to υ ₂ = υ ₁ + JkE (xt),

where j is the corona current density;

k is the mobility of negative ions ;

E (xt) is the law of variation of the field strength vector.

This ratio does not take into account the effect of electric wind.

The optimal geometry of the rods, mesh electrodes and the interelectrode distance for a given or used fan is determined solely by the capabilities of a high-voltage pulse generator at a given intensity of the “flare” corona.

Since the step of placing the rods on the mesh surface of the anode determines the intensity and / or quality of the electrostatic focusing of the air stream jets with an excess of electronegative ions, this value is selected from the optimal modes. For the chosen value of h, each rod of the discharge gap, in its shape of the corona and its intensity, has no effect on the neighboring ones. The system of rods (needles), protected by a dielectric barrier, provides unhindered passage of air with equally charged (sign) ions.

All streams of air flow contain almost the same concentration of negative ions and therefore, having passed a certain distance less than h / 2, due to the repulsive effect, they form an almost uniform medium.

In view of this, at a distance “b” = h / 2, a disk filter 10 is installed parallel to the grid of the electrode 6, made in the form of a honeycomb from a composite material, the filler of which is silica gel. Such a filter works on the principle of porous adsorption, providing deposition on the pore surfaces of both OH ^- group type ions (moisture) and OH-group free radicals, taking into account metal oxides and dioxides.

As a result, there will be an advantage of electronegative ions in the flow coming from the output of the device.

The use of a pulsed corona in the nanosecond range at a repetition rate f ₀ sufficient for the synthesis of oxygen-containing provides minimal electrical (energy) costs. So when introducing the concentration of negative ions N ^- ≥10 ¹³ cm ³ , costs of 150-170 W at a flow rate of 1 ÷ 1.5 l / s are sufficient.

Claims (1)

An air ionizer comprising a cylindrical body with a fan installed on the inlet end and two electrodes placed inside the body that perform the functions of a cathode and anode and connected to a power source, the cathode being made in the form of a grid, characterized in that the anode is made in the form of a grid with fixed on it perpendicular to the grid plane with staggered rods with a step equal to its height, and the entire surface of the grid and rods except the vertices of the latter is covered with a dielectric film, ode installed within the housing such that the distance from the fan to the anode is greater than the distance from the blower to the cathode by the value of the interelectrode distance is not less than twice the height of the rod, and as a power source used a high voltage pulse generator nanosecond range.