DE3611019A1 - ELECTROSTATIC SEPARATOR - Google Patents

Abstract

A two-stage electrostatic separation device in the form of an electrostatic filter cartridge (6) with a built-in neutralizer, which cartride can be incorporated in a tubular or rectangular casing (1). It is formed of foil electrodes (7) which are at different voltages and are separated by insulating foils (8). Ionization of the particles to be separated is effected via a UV source and/or in the space between an earthed grid electrode (4) and the edge of the foil electrode (7), which is at a high voltage, a high ion density being created in said space. The ionized particles are separated in the electrostatic filter cartridge (6) forming the collector. At the gas outlet from the electrostatic filter cartridge (6) a corona discharge with both ion polarities is produced between the earthed electrodes and the foil electrodes (7) which are at a high voltage (9), and thereby the operation of a neutralization zone (17) for the filtered gas stream is ensured.

Description

The prior art includes two-stage electrostatic precipitators. They have been known for about 35 years were developed for the purpose of high separation rates for solid particles, aerosols or under micronic To reach drops from the gas stream.

In the first stage of a known electrostatic precipitator is a charge of the solid particles Ions of a polarity using a so-called Ionizer stage performed.

The ionizer consists of electrodes and spray electrodes called, in the form of wires or tips that concentrate the electric field lines. These electrodes are between the counter electrodes consisting of parallel plates arranged. To the Spray electrodes form a plasma layer. The Ions of the plasma layer with the same polarity as the spray electrodes migrate to the counter electrodes. The solid particles that flow through this ion rain are charged electrically because themselves fix the ions on their surface.

In the second stage, the solid particles are made pulled out of the gas stream and on the plates one Fixed collector. The collector consists of separation plates, which are at different potential under high voltage and between which an electrical Field is generated. The electrically charged solid particles are flowing through the Collector, thanks to the electrostatic forces acting on it the charged solid particles in the electrical Field of the collector act, eliminated from the gas flow and deposited on the collector plates.  

In the patents
US 25 79 441 D. 19 55 692
US 25 02 560 D. 12 45 328
US 37 98 879 D. 23 46 196
US 25 04 430 D. 11 67 799
showing the current state of the art, various known designs of two-stage electrostatic precipitators are shown.

All described electrostatic precipitators, without exception, are complicated and expensive designs with a weight of sometimes about 30 kg, and lower all the electrostatic precipitators a complicated manufacturing technology.

The present invention describes an improvement the current state of the art and enables Manufacture of electrostatic filters for the filtration of solid particles or drops of gas or air with one higher degree of separation, especially for submicron Particles, ie in the range from 0.01 µm to 1 µm particle sizes.

The advantages of the present invention are numerous. An advantage is that such an electrostatic filter z. B. is much cheaper to manufacture, approximately 10 times cheaper than a classic two-stage Electrostatic precipitator, for the same amount of gas flow to be filtered.

The execution of this new electrostatic filter is very simple, the production is automated with little effort can be.

The implementation of the present invention allows one Reduction of the distances between the collector electrodes to the smallest distances, on the order of approximately 1 mm. The highest degrees of separation are achieved in this way. Realizing such small distances between the electrodes and the collector plates is with the so far existing electrostatic precipitators with metal plates impossible.  

The electrostatic filter described requires a single one High voltage supply.

The electrostatic filter described in the invention has a minimal weight. It's about 8 times easier than that Weight of a classic electrostatic precipitator because of the electrodes conductive foils, light in weight and less Thickness z. B. 0.1 mm to 0.3 mm can be used.

Another advantage is that the invention in each any tubular system, whether already on site or not, can be inserted. In addition cause the plus and generated by the electrodes Minusions at the exit of the gas flow from the electrostatic Filter cartridge a neutralization of the electrical room air charge.

By using electrodes with wider foils can easily filter the degree of separation be enlarged, by this measure, extension the cylindrical filter cartridge Separation levels from the field of HEPA filters with 99.99% degree of separation for smallest particles reached. An increase in the degree of separation can also be achieved by Increase the diameter of the spiral or cylindrical electrostatic filter cartridge generated will.

Another advantage is that the electrostatic Filter cartridge because cheap to manufacture, like any mechanical filter made of porous or fibrous Medium, when loaded with dust, with a new cartridge equipped and like any other mechanical filter can be replaced.  

In this way, the filter cartridge can be replaced as "hazardous waste" when the filtered aerosol is dangerous or toxic to the environment.
As a result, the current existing situation in which the electrostatic precipitator is cleaned and the toxic dust that is washed out of the electrostatic precipitator is discharged can be eliminated.

Thanks to its very low manufacturing price and its "hazardous waste" properties, this new type of electrostatic filters wherever radioactive particles must be filtered to use reach. For this reason, this is new electrostatic precipitator an ideal air filter for the nuclear industry where radioactive particles have to be filtered.

The current electrostatic precipitators cannot be used in the Filtration for radioactive particles can be used. This requires mechanical filters with a large pressure drop and high energy consumption. Another important advantage of this new type of Electrofilter is the separation of the electrodes from the insulating films so that even conductive particles can be filtered, which in most cases with the electrostatic filters offered by the current state of the art is not suitable.

The application of this invention in the filtration of a Oil mist is particularly cheap because of the electrode edges on the outlet side of the gas flow from the insulating Foils are separated, with the electric field lines no longer concentrate so intensely on the edges and the flowing oil film is no longer in one can transform secondary production of very fine oil drops.  

This secondary generation of very fine liquid Aerosol is a very unfavorable phenomenon for that current electrostatic precipitator. However, with this invention you can use the electrostatic precipitator oil mist or any Filter another mist with the highest degree of separation.

Also for very aggressive fog like e.g. B. acids and Lyes can be economical with suitable materials be deposited favorably. Through sufficiently large widths For the insulating foils, water vapor can also be used and droplets are separated.  

Further details and features of the present Invention in connection with the following Drawings described in more detail.

Fig. 1 shows an electrostatic separator with a UV light source 2 with a grid electrode 4 and an electrostatic filter cartridge 6 , consisting of spiral, insulating foils 8 and foil electrodes 7 , applied to a high voltage source 9 and which is mounted in a tubular housing 1 .

Fig. 2 shows a sectional view of a spiral-shaped electrostatic filter cartridge 6 in the housing 1.

Fig. 3 shows a zigzag-shaped insulating film 8 between the film electrodes 7 and the housing 1.

Fig. 4 shows a smooth insulating film 8 with the zigzag-shaped foil electrodes 7 installed in the housing 1.

Fig. 5 shows a possibility of the invention, in which the insulating films 8 are zigzag and the film electrodes 7 have been placed on top of each other, whereby a rectangular electrostatic filter cartridge 6 is formed.

FIG. 6 shows a possibility of the invention in which the insulating foils 8 have been laid flat and the foil electrodes 7 have been placed on top of one another in a zigzag shape, whereby a rectangular electrostatic filter cartridge 6 is created.

Fig. 7 shows a further possibility of folding of the insulating film 8 between the film electrodes 7 and the housing 1.

FIG. 8 shows a reversal of FIG. 7, the insulating foils 8 being smooth and the foil electrodes 7 being folded.

Fig. 9 shows a further possibility of a Verfaltungsart the insulating foils 8.

Fig. 10 shows an embodiment of an electrostatic precipitator, in which the insulating film 8 and the film electrodes 7 cylindrical axially reciprocally disposed an electrostatic filter cartridge 6 form, which has been installed in a housing 1.

Fig. 11 shows an embodiment of the invention, in which the electrostatic filter cartridge 6 , which can be cleaned by an automatic washing device with an ultrasonic generator 16 , where a cleaning liquid 10 flows in by means of a filler tube 11 , which can flow out of the drain valve 12 after use.

Fig. 12 shows an embodiment of the invention, in which the gas flow in the region of the core and in the edge region of the electrostatic filter cartridge 6 to the housing 1 is passed through a gas flow guide 13.

FIG. 13 shows an embodiment of the invention in which a liquid 15 is sprayed onto the electrostatic filter cartridge 6 by means of a nozzle 14 , whereby a wet separator is created.

The principle of operation of the present invention is shown in FIG . A gas stream flows through a housing 1 and is irradiated by a UV source 2 and its UV rays 3 . It is then passed through a grid electrode 4 and ionized in the ionizer zone 5 by an ion rain.

Positive or negative ions are generated in the ionizer zone 5 . They result from a corona discharge between the spiral edge, which is under high voltage potential 9 .

The solid particles flow from the first ionization zone, consisting of the UV source 2 and the second ionization zone 5 , where the further ionization of the gas flow takes place by means of so-called ionic bombardment, into the so-called electrostatic filter cartridge 6 .
This contains the spiral foil electrodes 7 , which are applied to different polarized potentials and are separated by insulating foils 8 . In Fig. 1 it can be clearly seen that the length of the insulating films 8 protrude beyond the film electrodes 7 , producing the so-called insulation distance.

Thanks to the electrostatic forces, the solid particles in the gas stream, which are electrically charged after the ionization stage, are pulled out of the gas stream in the space between the film electrodes 7 and deposited on the surface of the grounded film electrode and also on the surface of the highly polarized insulating films 8 .

A so-called fourth stage is formed by a neutralizer 17 . The neutralizer zone 17 is shown on the gas outlet side of the electrostatic filter cartridge 6 . The fourth stage is formed by the edges of the spiral foil electrodes 7 , which generate a corona discharge against one another by concentrating the field lines. As a result, ions of both polarities are generated, which in this way produce an electrical neutralization of both the gas flow and the objects possibly located in the space into which the gas flow flows.

It is also shown that the insulating foils 8 have an offset with respect to the foil electrodes 7 and that a necessary insulation distance is thereby achieved.

Further, 1 is shown in Fig. Can be seen that a helical insulating film 8 is inserted between the grounded housing 1 and connected to a high voltage potential 9 foil electrode 7, the electrostatic filter cartridge 6 to the housing 1 isolated.

In FIG. 2 a spiral embodiment is shown an electrostatic separation device. The sectional view shows the top view of the electrostatic filter cartridge 6 . It can clearly be seen that the ends of the insulating film 8 protrude beyond the ends of the film electrodes 7 , so that there is a safe insulation distance. It can also be seen that between the housing 1 and the film electrode 7 , which has been applied to a positive high-voltage potential 9 , and an insulating film 8 is inserted.

In Fig. 3 the layered structure of an electrostatic filter cartridge 6 is shown in a sectional view. In this case, the zigzag films are insulating films 8 . The foil electrodes 7 are smooth foils. It can also be clearly seen here that an insulating film 8 is inserted between the outer film electrode 7 and the housing 1 .

In FIG. 4, the layered structure of an electrostatic filter cartridge 6 in a sectional view is shown. In this case, the foil electrodes 7 are folded in a zigzag shape and the insulating foils 8 are smooth foils. In this case too, an insulating film 8 is inserted between the housing 1 and the outer film electrode 7 .

A further possibility of the invention is shown in FIG . In this case, zigzag-shaped insulating foils 8 are placed one on top of the other with foil electrodes 7 . Rectangular electrostatic filter cartridges 6 can also be produced by this type of production.

In Fig. 6 a possibility is shown, as already described in Fig. 5. Here zigzag-shaped film electrodes 7 are inserted between insulating films 8 , so that, for. B. rectangular electrostatic filter cartridges 6 arise.

A further embodiment of the folded, insulating foils 8 is shown in FIG. 7. The film was folded round and, as already described in FIG. 3, wrapped between the film electrodes 7 .

In FIG. 8, like in FIG. 4, however, the film, which has been folded round, is processed into an electrostatic filter cartridge 6 .

In Fig. 9 a further possibility of Verfaltungsart is shown. Layer structure and function of the electrostatic filter cartridge 6 are retained.

FIG. 10 shows an embodiment in which the film electrodes 7 and the insulating films 8 represent cylindrical bodies which, when placed axially one inside the other, form an electrostatic filter cartridge 6 . In this case too, an insulating film 8 is inserted between the outer film electrode 7 and the housing 1 .

In Fig. 11, a possibility is shown in which an automatic cleaning or regeneration of the electrostatic filter cartridge 6 is possible. If the electrostatic filter cartridge 6 has to be cleaned of the attached dust or aerosols, the filtration of the gas stream and the supply of electrical energy must be interrupted by the high voltage potential 9 . Once this has been done, the U-shaped housing 1 can be filled with a cleaning liquid 10 by means of a filler tube 11 until the electrostatic filter cartridge 6 is flooded. After this process, an ultrasound generator 16 is switched on, which causes the cleaning liquid 10 to vibrate. The vibrations detach the deposited solid particles from the film electrodes 7 and the insulating films 8 . The detached solid particles sink in the cleaning liquid 10 in the direction of the drain valve 12 . By means of the drain valve 12 , the cleaning liquid 10 with the solid particles can be drained and renewed if necessary.

With this device, even in the case of filtration of an oil mist or other mist-like liquids, the filtered material can sink down, collect in the lower part of the U-shaped housing 1 and be drained from there, so that a recovery of the filtered liquid aerosols is possible.

FIG. 12 shows an embodiment in which the gas flow flowing into the housing is passed through gas flow guides 13 which are arranged directly in front of the electrostatic filter cartridge 6 . This makes it possible to direct the gas flow in such a way that it cannot flow through the spaces between the housing 1 and the electrostatic filter cartridge 6 . The same applies to the core area of the electrostatic filter cartridge 6 . The gas flow guide 13 is necessary because the core area and the edge area are zones with a lower degree of separation.

In Fig. 13 an electrostatic filter device is shown, a liquid is sprayed 15 to the electrostatic filter cartridge 6 in the means of a nozzle 14. This creates a wet electrostatic precipitator with a high degree of separation.

• 1 housing
  2 UV source
  3 UV rays
  4 grid electrode
  5 ionizer zone
  6 electrostatic filter cartridges
  7 foil electrode
  8 insulating film
  9 high voltage potential
  10 cleaning liquid
  11 filler pipe
  12 drain valve
  13 gas flow guide
  14 nozzle
  15 liquid
  16 ultrasonic generator
  17 neutralization zone

Claims (16)

1. Electrostatic separation device, two-stage, with an ionizer and a collector for separating solid particles, drops or aerosols, consisting of spirally wound at least two foil electrodes ( 7 ) connected to different potential, which are separated from one another by zigzag-shaped insulating foils ( 8 ) and between keep the foil electrodes ( 7 ) at a constant distance, thereby ensuring that a gas flow passes through the spaces between the electrostatic filter cartridge ( 6 ), the geometric shape of the electrostatic filter cartridge ( 6 ) being cylindrical or else being rectangular, characterized in that that a spiral edge on the gas inlet side is connected to a high voltage potential ( 9 ) and a corona discharge occurs against a grounded grid electrode ( 4 ), whereby an inflowing gas stream gets a large ion density of a single polarity, thus e An ionization zone for the gas flow is formed before it enters the electrostatic filter cartridge ( 6 ), the gas outlet side of the electrostatic filter cartridge ( 6 ) being grounded at the edges of both foil electrodes ( 7 ), one of which is earthed and the other of which is at a high voltage potential ( 9 ) is galvanically connected and generates a corona discharge against each other, whereby ions of both polarities are generated, thereby forming a neutralization zone ( 17 ) for the outflowing gas stream and the spiral edges of the insulating zigzag film ( 8 ) opposite the edges of the film electrodes ( 7 ) at the gas inlet - And protrude the gas outlet side at least 5 mm, and that the beginnings and ends of the spiral insulating foils ( 8 ) exceed the beginnings and ends of the foil electrodes ( 7 ) by at least 5 mm, and that on the gas inflow side of the electrostatic filter cartridge ( 6 ) two gas flow guides are located, sod ate the gas flow when entering and passing through the spaces between the electrostatic filter cartridge ( 6 ) and the housing ( 1 ), and in the core area of the electrostatic filter cartridge ( 6 ) cannot pass. 2. Electrostatic separation device according to claim 1, characterized in that the spiral foil electrodes ( 7 ) are zigzag and are separated by two insulating foils ( 8 ) which are placed one on top of the other and spirally wound together to form a compact spiral electrostatic filter cartridge ( 6 ). 3. Electrostatic separating device according to claim 1 or 2, characterized in that at one of the edges of the spiral foil electrodes ( 7 ) the gas inflow side of the electrostatic filter cartridge ( 6 ) is in the form of tips which generate ions of polarity by corona discharge. 4. Electrostatic separation device according to claim 1 up to 3 characterized that the electrical charge of the solid particles performed in a separate ionizer being, the two spiral electrodes that separated from spiral foils, only one Represent collector pack.   5. Electrostatic separator according to claim 1 to 4, characterized in that the electrostatic filter cartridge ( 6 ) can be installed in a cylindrical or rectangular housing ( 1 ). 6. Electrostatic separator according to claim 1 to 5, characterized in that the solid particles in the gas stream before they enter the electrostatic filter cartridge ( 6 ) with ultraviolet rays ( 3 ), by means of a UV source ( 2 ), are irradiated. 7. Electrostatic separator according to claim 1 to 6, characterized in that the spiral foil electrodes ( 7 ) consist of a conductive polymer. 8. Electrostatic precipitator according to claim 1 to 7, characterized in that the distance between the spiral foil electrodes ( 7 ) and the spiral insulating foils ( 8 ) due to the presence at certain points of the spiral of sikken or waves or threads or other deep-drawn shapes that differ located on the foils wound together, ensure a safe distance from each other. 9. Electrostatic separation device according to claim 1 to 8, characterized in that the foil electrodes ( 7 ) and the insulating foils ( 8 ) which separate them are not spiral, but are axially arranged individual cylinders of different diameters, which are set into one another an electrostatic filter cartridge ( 6 ) form or that the foil electrodes ( 7 ) and the insulating foils ( 8 ) lie planar one above the other. 10. Electrostatic separator according to claim 1 to 9, characterized in that the electrostatic filter cartridge ( 6 ) only / and also the ionizer zone ( 5 ) is installed in a U-shaped tube which can be filled with a cleaning liquid ( 10 ) with which the electrostatic filter cartridge ( 6 ) can be flooded and cleaned, the tube having a drain valve ( 12 ) on its lower curved side for exchanging the cleaning liquid ( 10 ). 11. Electrostatic separator according to claim 1 to 10, characterized in that inside or outside the U-shaped tube, in the region of the electrostatic filter cartridge ( 6 ), there is an ultrasonic generator ( 16 ) which transmits its vibrations to the electrostatic filter cartridge ( 6 ) , wherein the entire mass of the cleaning liquid ( 10 ) receives the vibration of the ultrasonic generator ( 16 ) and a cleaning of the electrostatic filter cartridge ( 6 ) is initiated. 12. Electrostatic separator according to claim 1 to 11, characterized in that the spiral foil electrodes ( 7 ) can be supplied with DC voltage. 13. Electrostatic separator according to claim 1 to 12, characterized in that the spiral foil electrodes ( 7 ) can be supplied with AC voltage. 14. Electrostatic separation device according to claim 1 to 13, characterized in that the insulating films ( 8 ) consist of a material polarizing in the electric field. 15. Electrostatic separator according to claim 1 to 14, characterized in that there is a nozzle when gas enters the electrostatic filter cartridge ( 6 ) through which the electrostatic filter cartridge ( 6 ) is moistened with a liquid ( 15 ), so that a wet electrostatic filter is formed. 16. Electrostatic separator according to claim 1 to 15, characterized in that the outer spiral foil electrode ( 7 ), which encloses the entire electrostatic filter cartridge ( 6 ), is applied to a high electrical potential and from the housing ( 1 ) by an insulating film ( 8 ) is isolated.