RU2687934C1 - Electrostatic device for collection metal dust from surface - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to devices for cleaning surface using electrostatic field, including for cleaning of inner walls of tokamak to prevent accumulation of dust in thermonuclear plants. Electrostatic device for collection of metal dust contains a metal reservoir, upper and lower sides of which are formed by two horizontal rectangular plates, three vertical side walls and an inlet grid. Input grid connects the top and bottom sides of the tank. Upper side of the reservoir is longer than the lower one; as a result, the input grid is inclined at an acute angle to the horizontal. Reflector in the form of a rectangular metal plate equal in size to the input grid is attached to the upper edge of the input grid. Angle between the reflector and the upper side of the reservoir lies in range of 100–160º, and the lower side of the reflector is located in the same plane with the lower side of the reservoir.

EFFECT: higher efficiency of dust collection from surface, as well as increase of maximum mass of dust, which can be collected in reservoir.

8 cl, 1 dwg

Description

The invention relates to devices for cleaning the surface using an electrostatic field, including cleaning the inner walls of the tokamak to prevent dust accumulation in thermonuclear installations, which can significantly affect the plasma parameters and lead to the accumulation of unacceptably large amounts of tritium.

A device using an electrostatic field for cleaning the surface from small particles is known (Douglas W. Cooper, Henry L. Wolfe, James T.C. Yen & Robert J. Miller (1990) Surface Cleaning Electrostatic Removal of Particles, Aerosol Science and Technology, 13: 1, 116-123). The principle of the device is based on the principle of electrostatic dust collection in a condenser consisting of two plane-parallel plates arranged one above the other, the upper plate is covered with a dielectric. A potential difference is applied between the plates, with the result that a homogeneous electrostatic field arises in the space between the plates. Particles lying on the bottom metal plate acquire a charge in an electrostatic field. If the electrostatic force exceeds the sum of the adhesion and gravity forces, the particle detaches from the surface, is attracted to the upper electrode and is held on it while the electrostatic field is present. However, this design does not allow to hold the collected particles after turning off the electric field. In addition, this design does not allow for the accumulation of particles, so the maximum number of collected particles is limited by the surface area of the upper electrode, and after the particles occupy the entire surface of the upper electrode, the surface will not be cleaned.

The closest to the invention is a device for collecting metal dust from the surface by the electrostatic method (L.V. Begrambekov et al 2016 J. Phys .: Conf. Ser. 748 012004), which is taken as a prototype. The device consists of a metal tank, the lower side of which is made of a flat plate, the upper and lower sides of which are formed by two horizontally arranged rectangular plates, three vertical side walls, and an inlet grid connecting the upper and lower sides of the tank, and the upper side is longer than the lower one, so that the grate is inclined at an acute angle to the horizontal. A tank located at some distance above a grounded plate with dust is energized relative to it. The dust particles are charged in the electrostatic field, are attracted to the reservoir and through the inlet grate fly into the equipotential space of the reservoir. The main part of the dust particles collected in the reservoir accumulates on its underside.

However, the device does not have a sufficiently high efficiency, since some particles flown into the tank are reflected from internal surfaces and can fly back. The emitted particles are reflected from the grounded plate and can leave the collection area, scattering in different directions, since they have a speed directed to the opposite side of the reservoir. Another drawback of the device is that it has a small capacity, since particles in the tank occupy only a third of the bottom side, accumulate near the inlet lattice, prevent new particles from entering the tank and may be lost during transportation. In general, these drawbacks of the device make the process of collecting dust from the surface ineffective.

The technical result of the invention is aimed at improving the efficiency of collecting dust from the surface, as well as increasing the maximum mass of dust that can be collected in the tank.

The technical result is achieved in that the device for collecting metal dust from the surface by the electrostatic method, consisting of a metal tank, the upper and lower sides of which are formed by two horizontally arranged rectangular plates, three vertical side walls, and an input grid connecting the upper and lower sides of the tank the upper side is longer than the lower one in such a way that the grate is inclined at an acute angle to the horizontal, while it additionally contains a reflector, in Made in the form of a rectangular metal plate, the upper side of which is attached to the upper edge of the lattice, equal to it in size so that the angle between the reflector and the upper side of the tank lies in the range of 100-160 °, and the lower side is in the same plane with the bottom side of the tank .

The reflector allows you to increase the efficiency of collecting particles in the tank due to the reflection back of the particles leaving the collection area after departure from the equipotential space of the tank or reflection from the input grid. In case the angle between the reflector and the upper side of the tank is more than 160 °, a significant part of the particles after reflection from it will have a speed directed to the side opposite to the entrance lattice, this means that after several reflections from the overgrown plate and reflector they will leave the collection area taking off from under the reflector. If the angle between the reflector and the upper side of the tank is less than 100 °, a significant part of the particles after reflection from it falls into the gap between the bottom and the grounded plate and leave the collection area. So that after hitting the reflector, most of the particles after reflection from a grounded plate fall into the tank, the angle between the reflector and the upper side of the tank should lie in the range of 100-160 °.

In the particular case, two metal plates are additionally installed that extend the sides of the tank until they intersect with the reflector, and the lower edges of these side plates are in the same plane with the bottom side of the tank. The side walls limit the dispersion of dust particles from the collection area.

In addition, on the inner surface of the reflector there are additionally installed vertical lamellae, made in the form of straight metal strips parallel to each other, located in the direction perpendicular to the line of intersection of the reflector with the upper side of the tank so that particles flying up to the reflector and falling into the gap between the lamellae lose a significant part of the energy, as well as the velocity component directed towards the side walls, which reduces the number of particles flying apart, thus, increased It detects the efficiency of collecting particles in the tank.

In the particular case on the inner surface of the reflector are additionally installed in a direction parallel to the line of intersection of the reflector with the upper side of the tank, lamellas made in the form of straight metal strips and located in the direction parallel to the line of intersection of the reflector with the upper side of the tank, so that particles flying up to the reflector and falling into the gap between the lamellas lose a significant part of the energy, and also so that the particles emitted from the gap have a velocity directed normal to the plane bones of the reflector, which reduces the number of particles flying forward from under the reflector after colliding with it, thus increasing the efficiency of collecting particles in the tank.

In addition, to achieve the best efficiency of dust collection from the surface, the lamellas described in the two previous paragraphs can be installed on the inner surface of the reflector simultaneously. This allows you to simultaneously reduce the number of particles flying to the sides and flying forward from under the reflector.

In the particular case, on the inner surface of the lower side of the tank, parallel lamellae are installed parallel to each other, made in the form of straight metal strips arranged parallel to the line of intersection of the reflector with the upper side of the tank. They are designed to ensure that particles flown into the tank and approaching its underside, fall into the gap between the lamellae, undergo multiple collisions with them and, thus, lose a significant part of the energy. This reduces the number of particles with enough energy to fly back from the tank, thereby increasing the efficiency of collecting particles into the tank.

In the particular case, on the inner surface of the upper side of the tank, parallel to each other, vertical lamellas are installed, made in the form of straight strips and parallel to the line of intersection of the reflector with the upper side of the tank. In this case, particles flown into the tank and heading to its upper side fall into the gap between the lamellae, undergo multiple collisions with them and, thus, lose a significant part of the energy. Such particles under the action of gravity in the equipotential space of the tank fall on its lower side, where the collected dust accumulates. Thus, the number of particles with sufficient energy to fly out of the tank after a series of collisions with its walls decreases, which makes it possible to increase the efficiency of collecting particles into the tank.

In addition, the lamellae mounted on the inner surface of the upper side of the tank can be inclined at an acute angle in the range from 0 to 60 ° to the vertical side away from the reflector so that the particles ejected from the gap between the lamellae have a speed directed away from the entrance grid, to the opposite wall of the tank, and thus distributed at the bottom of the tank evenly, and not at the entrance grid. This will prevent dust from escaping from the tank when a large amount of dust accumulates there, and also the accumulated dust near the entrance grate will now cease to prevent new particles from entering the tank. Thus, the number of particles accumulated in the tank will increase.

Below is an example of a specific implementation of the proposed device.

FIG. 1 shows a diagram of one of the variants of the proposed device, where 1 is a reservoir; 2 - reflector; 3 - lamellas on the upper side of the tank; 4 - lamellae on the underside of the tank; 5 - slats on the reflector; 6 - the upper side of the tank; 7 - the bottom side of the tank; 8 - grounded metal plate, which collects dust 9; 10 - entrance lattice.

The device works as follows.

The tank 1, equipped with a reflector 2 and lamellas 3, 4, 5, mounted on the upper side of the tank 6, the lower side of the tank 7 and the reflector, respectively, as well as two plates extending the sides of the tank to the intersection with the reflector, is located at a distance d above the grounded plate 8, on which dust 9 is located (tungsten particles of various shapes, the sizes of which lie in the range of 5–60 μm). The tank is supplied with a voltage U relative to the grounded surface. Metallic dust particles acquire a charge q in the resulting electrostatic field and begin to attract themselves to the reservoir. When the field strength is such that the Coulomb force F _q exceeds the gravity force F _mg and the force of adhesion of particles to the plane F _adh on which they initially lie, the particles begin to detach from the surface.

The value of F _q required for the separation of the dust particles is determined by formula 1. The magnitude of the adhesion force of particles of the selected group was determined experimentally, its value approximately exceeded the force of gravity by 12 times. In this implementation of the proposed device d = 4 mm. This value was chosen in such a way that the obtained value of F _q for this group of dust particles is achieved when the values of U lie in the range of 2000–6000 V (formulas 2 and 3). The value of q for particles of a spherical shape was calculated using formula 3, and for particles of a more complex shape was obtained using numerical simulation. Magnitude

where r is the radius of the particle.

Part of the particles, which lies under the entrance grate 10, begins to move towards the tank, flies through the entrance grate, gets into the gaps between the lamellae on the upper side, loses most of the energy during collisions with them, and then falls on the lower side of the tank, where it accumulates . The size of the gap between the lamellae was selected experimentally and was 0.5 mm for the dust particles used. Those particles that have not lost their energy, lose it, undergoing collisions with lamellae on the lower side, and remain there. Another part of the particles, which lies under the reflector, begins to be attracted towards the reflector, gets into the gap between the lamellae, reloads upon contact with the reflector or lamellae and begins to be attracted to the plate with which it started. Moreover, since the acceleration is directed along the power lines of the electric field, the particles arriving on the plate are displaced from the initial position to the strontium of the input lattice. After contact with a grounded surface, the particles are recharged again, then everything repeats again until all the dust collects on the underside of the tank.

Thus, it follows from the above that the proposed device allows collecting metal dust from the surface with great efficiency, as well as obtaining an even distribution of the collected dust at the bottom of the tank, which will allow to transport the tank without risk of spilling the collected dust. Thus, the use of the device leads to an increase in the efficiency of the technological process of collecting metal dust from the surface.

Claims (8)

1. Electrostatic device for collecting metal dust from the surface, consisting of a metal tank, the upper and lower sides of which are formed by two horizontally positioned rectangular plates, three vertical side walls and an inlet grid connecting the upper and lower sides of the tank, and the upper side is longer than the bottom that the entrance grating is inclined at an acute angle to the horizontal, characterized in that it additionally contains a reflector, in the form of a rectangular metallic n ASTINA upper side of which is attached to the upper edge of the grating equal to s size in such a way that the angle between the reflector and the upper side of the tank lying in the range 100-160 °, and wherein the lower side is located in the same plane with the lower side of the tank. 2. The device according to claim 1, characterized in that two metal plates are additionally installed that extend the sides of the tank until they intersect with the reflector, and the lower edges of these side plates are located in the same plane with the bottom of the tank. 3. The device according to claim 1, characterized in that on the inner surface of the reflector there are additionally installed vertical lamellae, made in the form of straight metal strips parallel to each other, located in the direction perpendicular to the line of intersection of the reflector with the upper side of the tank. 4. The device according to claim 1, characterized in that on the inner surface of the reflector there are additionally installed lamellae perpendicular to the reflector, made in the form of straight metal strips and located in the direction parallel to the line of intersection of the reflector with the upper side of the tank. 5. The device according to claim 1, characterized in that on the inner surface of the reflector simultaneously installed vertical lamellae, made in the form of straight metal strips parallel to each other, located in the direction perpendicular to the line of intersection of the reflector with the upper side of the tank and the lamellae perpendicular to the reflector, located in the direction parallel to the line of intersection of the reflector with the upper side of the tank 6. The device according to claim 1, characterized in that on the inner surface of the lower side of the tank, parallel lamellae are installed parallel to each other, made in the form of straight metal strips arranged parallel to the line of intersection of the reflector with the upper side of the tank. 7. The device according to claim 1, characterized in that on the inner surface of the upper side of the tank parallel to each other vertical lamellae are installed, made in the form of straight metal strips and arranged parallel to the line of intersection of the reflector with the upper side of the tank. 8. The device according to claim 7, characterized in that the lamellae mounted on the inner surface of the upper side of the tank are inclined at an acute angle in the range from 0 to 60 ° to the vertical direction away from the reflector.

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