DE2842718A1 - Electrostatic precipitator for dust-laden gases - with granular insulating particles circulating between charged electrodes - Google Patents

Abstract

An electrostatic precipitator for the dedusting of gas passes the gas through the gaps of a granular insulating material between two electrodes to which a voltage is applied. The apparent resistance of the packed insulator is kept >5.108 ohm.cm. One of the electrodes has sections with points where a high electrostatic field intensity is produced. The arrangements requires low voltages to produce multipolar discharges. The regeneration of the dust laden particles is simplified. The insulator can at the same time ba a catalyst so that the dust adheres to the surface and the catalytic activity is not affected.

Description

Electrostatic precipitator and its use. to the

Removal of dust from an exhaust gas containing dust. The invention relates to an electrostatic precipitator, with the help of which dust is continuous or dust and nitrogen oxide (NOx) are removed from a gas containing dust can, as well as a method for removing dust from a dust containing Exhaust gas carried out using such a precipitator.

The invention particularly relates to an electrostatic precipitator, with the help of which dust can be removed from a gas containing dust in this way can that a particulate insulator is filled between two electrodes and a gas containing dust through the interstices of the particulate insulator is conducted while a voltage is applied to the electrodes, the Dust in the dust-containing gas on both the particulate insulator and also adheres to an electrostatic precipitator, which is also dust.

and nitrogen oxide in a dust-containing gas in the manner remove can that catalyst particles in the form of a particulate insulator between two electrodes are filled and a gas containing dust into the ammonia has been injected, passed through the interstices of the catalyst particles while a voltage is applied to the electrodes.

As a so-called electrostatic filter that can collect dust through Passing a gas containing dust through the interstices of an insulator, to which a voltage is applied has hitherto been widely used of the type in which the dust is collected on the insulator by electrostatic forces , of the type in which the dust is charged by a corona discharge before the gas containing dust is passed through the space of the insulator, and like

used.

A number of improved devices have also been developed for these types such as in Japanese Utility Model Publication No. 31 178/1976 (Japanese Utility Model Application No. 103 822/1974) in Japanese Patent Publication No. 2467/1975 (Japanese Patent Application No. 107 398/72), in Japanese Patent Publication No. 120 273/1974 (Japanese Patent Application No. 31834/1973) and the like and an improved one A method for removing nitrogen oxide from an exhaust gas was already in the Japanese Patent Publication No. 95870/1974 (Japanese Patent Application No. 8 068/1973) suggested.

Figure 1 of the accompanying drawings illustrates one of the conventional ones Types, which is explained below as the most representative example of the prior art will.

In Fig. 1 of the accompanying drawings, the dust containing flows Gas in the direction of the arrow, during which time the dust passes through the between the Discharge electrode 4 and the grounded electrode 5 generated corona discharge electrified is, and while it is through the interstices of an insulator 3 between the high voltage electrode 1 and the grounded electrode 2 is passed through, the dust on the insulator 3 collected and removed as a result of the Coulomb force by the electric field.

In this process, the electric field is in the gaps of the insulator, the higher the applied to the high-voltage electrode 1, the stronger Tension is so that the dust removal efficiency is improved, it exists however, the disadvantage is that if the voltage gets too high, sparks are generated, which cause the insulator to deteriorate or burn and also that the electric current becomes unstable, making control difficult will.

It has now been found that when a part-shaped insulator is filled (packed) between two electrodes and a high voltage is applied to the Electrodes is applied, the electric field strength in the interstices of the particulate insulator becomes higher than in the particulate insulator itself and that as a result, multipolar discharges arise in the interstices, the particulate insulator forming the poles so that if dust or Like. Is present in the gap, this electrifies in a very effective manner can be and In addition, the one electrified in this way Dust accumulates on the surface of the particulate insulator so that the combination of these features led to the development of a new device.

In the device according to the invention, the discharge zone is not only through the cavity in the particulate, insulator that is in a given There is an area centered around a high-voltage electrode, but also formed by the cavity of the particulate insulator, which in a corresponding area around a grounded electrode is centered. The size of this area (the discharge zone) is determined by the applied voltage.

In the space of the particulate insulator outside the discharge zone the electric field strength is very high, even without a multipolar discharge. Since all Particles of the particulate insulator in the discharge zone as a pole for generation of multipolar discharges between the particles, as indicated above, act, the dust in the gas passed through these gaps can be very high effectively positively or negatively electrified (charged) and the result of which is that the electrified (charged) dust is immediately removed from the surfaces of the particulate insulator in the neighborhood is attracted.

As is readily apparent from the above explanation, in the device according to the invention, the electrification and the collection of dust carried out according to a completely new technique, in which the mechanism of electrification just as the mechanism of dust collection is completely different from those in the conventional dust collection system using corona discharge.

Compared to the Cottrell system, in which the corona discharge electrified dust migrates to the dust collecting electrode through a gas the system according to the invention, in which the dust on the adjacent surface of the particulate insulator is collected from the standpoint of the dust collecting effect from a point of view an excellent system, as can be easily understood. In addition, the recovery of the dust collected on the electrodes contributes to the conventional Cottrell dust collector a knock or the use of a so-called Wet process in which the dust collecting electrodes are washed with water, the flows over their surfaces. In the system according to the invention, the dust loaded particulate insulator removed from the electric field and then the dust is separated. For this reason, the system of the present invention is industrial excellent also from the standpoint of performing dust recovery such as the operation control, the implementation of the dust collection process and the like considered.

One of the most important conditions in the device according to the invention as well as in the method according to the invention is the apparent electrical resistance of the particulate insulator. More apparent under the term used here electrical resistance "is not to be understood as the electrical resistance the particulate insulator itself, but the electrical resistance, denotes a packed layer of a defined thickness as Whole, when a defined electrical current is applied to one end of a particulate layer is applied by filling (packing) the particulate insulator in a Vessel has been made without any special pressing.

The apparent electrical resistance varies depending on the packed apparent density (bulk density, the mutual contact state of the particles, the atmosphere within the particulate layer such as the Temperature, humidity, gas properties, the amount of adhering dust and the like, besides the volume resistivity of the particles themselves. If the Volume resistivity of the particles is small, so is the apparent electrical Resistance small, so that when a voltage is applied, the current flows through the particles flow without creating a high voltage. On the other hand, it can even if the particles constituting the packed layer have a large specific Volume resistivity (specific resistance), it happens that the apparent Resistance is low according to the conditions described above, wherein in this case the current likewise flows over the surfaces of the particles without that a high tension arises.

For the reason given above, it is essential according to the invention to use a particle insulator whose specific volume resistivity (specific Resistance) is above 109 ohms x cm, with the condition that its apparent electrical resistance is above 5 x 108 Ohm x cm. Even then, when the apparent electrical resistance is small when a large current is applied multipolar discharges can occur, but this is for the large-scale or industrial use too uneconomical. In the case of the particulate insulator, which can be used for the purposes of the present invention is Particles that are non-flammable and very resistant to abrasion, being more specific Volume resistivity greater than 109 ohm x cm, preferably greater than 1013 ohm x cm and it is also expediently spherical, cylindrical or indefinite Shape and the like, but it is not critical, although they are suitably small Represent particles with a diameter of 1 to 10 mm.

The advantages of the insulator used in particulate form are the following: as the porosity becomes small, by applying a low voltage discharges are easily generated; the surface area of the insulator, which acts as a dust collecting electrode works, can be enlarged; in the removal, regeneration, etc. of the dust loaded isolator, it is easy to handle and the like.

At room temperature, various insulators have the following specific ones Volume resistances (specific resistances): glass> 1013, sulfur 1016 bis 1017, feldspar porcelain 1013 to 1014, steatite 1010 to 1012 titanium oxide> 1014, Gravel sand 1013 to 1014 aluminum oxide> 1013 ohms x cm and take all these values when the temperature rises. It should also be noted that the electrical Intrinsic resistance of every material includes the surface resistivity that obtain when an electric current flows over the surface of the material that He, however, as the value varies depending on the moisture content of the Gas over the surface or the substances that adhere to the surface, the invention Apparent resistance strongly influenced.

When the temperature of the particles is low and the moisture content of the exhaust gas is high, the electrical resistance becomes smaller as a result of the Particle surface adheres moisture, even if particles are used, whose volume resistivity is 1013 ohms x cm or more, so that it it is necessary to increase the temperature of the exhaust gas or the particles in order to achieve the To prevent the apparent resistance from falling due to the influence of moisture. Even if the dust is an electrically conductive material such as carbon powder and the like, the adherence of the dust causes the electrical resistance to decrease, so that the apparent electrical resistance is kept at 5 x 10 ohms x cm or more should be achieved by frequently removing the particulate insulator from the electric field to remove the dust from the insulator surface.

To electrify the dust in an exhaust gas in a stable state, it is necessary that stable multipolar discharges between the insulator particles be generated.

In a method for generating stable multipolar discharges it is most useful to connect to any electrode with pointed points (spikes) or knife cutting a high Apply voltage and the electrical Field strength only extreme in the area that is centered around the electrode to make high. If an alternating voltage or a high frequency voltage is applied to the Electrode with sharp points (spines) or knife edges is applied the particulate insulator removed from the electrode as an insulator in a silent discharge, while when a DC voltage is applied, the current density in the vicinity of the electrode is made large to produce multipolar ones Discharges, whereby the current density decreases at a distance from the electrode, so that the current flows through the interior of the particulate insulator or across the surface the same flows.

Therefore, when a DC voltage is applied, it is necessary to the apparent electrical resistance of the particulate insulator is less than 2 x 1011 ohms x cm to keep the current through the inside or over the surface of the particulate insulator can flow.

In another method of creating stable multipolar An alternating voltage can be applied to the electrodes with discharges covered with an insulating material, as in the case of silent discharge. at this method can when using a particulate layer with a apparent electrical resistance of 5 x 108 ohms x cm or more as an insulator stable multipolar discharges even by using.

Plate-plate electrodes are created, however, if sharp points (Spines) or knife edges are provided in at least one of the electrodes, a better effect can be achieved.

The extraordinary advantage of the electrostatic according to the invention Precipitator is based on the fact that both the electrification of the dust as well as the adhesion of the dust to the particulate insulator surface Coulomb forces are generated by the same mechanism, so that its structure is very simple, without the need to separate electrodes for electrification and to provide for dust collection, as is the case with the conventional electrostatic Precipitators is the case. In addition, the invention has electrostatic Precipitator also has the advantage that, since the discharges are within the interstices of the particulate insulator are generated even when the electrified Dust particles are reintroduced after they have already passed the particulate Had the insulator stuck and then lost the charge, electrified it again and collected on the particulate insulator so that the effectiveness of the Collection is very high compared to the conventional system.

According to a preferred embodiment of the invention, the inventive electrostatic precipitator also for the simultaneous implementation of the dust collection and denitration from an exhaust gas containing nitrogen oxide (NOx) and dust can be used in such a way that the particulate insulator is a particulate Denitration catalyst with a denitration activity used and ammonia is injected into the exhaust gas.

Although attempted in some of the conventional denitrification devices dust collection and denitration at the same time to carry out high voltage was not applied and the dust particles became due to their inertia from which it follows that extremely fine dust particles are discharged as they are without being collected, making the effectiveness of dust collection inevitable is decreased.

In the case of the preferred embodiment described above The catalyst used in the invention should be one which has an activity for the reaction between ammonia gas and NO, the Material itself consists of x an insulator that is molded into such a shape has been brought, their apparent electrical resistance in the packed state higher than 5 x 108 ohms x cm.

Products that are used today to a large extent as a catalyst for the reaction are used between ammonia gas and NO, x are aluminum oxide and titanium oxide and when these are used in the particulate form as conveyed by them same by molding it into a spherical, cylindrical, or indefinite shape with a diameter of 1 to 10 mm is obtained, its electrical resistance is 1012 ohms x cm or more so that they meet the requirements of the invention.

The catalyst suitable for practical purposes varies depending on the temperature, the sulfur content and the like.

of the exhaust gas, but preferably one applied to a copper carrier Catalyst in the form of balls with a diameter of 4 to 6 mm and the like. Used.

Regarding the multipolar discharges that occur within the interstices of particulate catalyst produced in accordance with the present invention are as follows Advantages to be expected: 1.) As the dust particles preferentially on the convex surface of the particulate catalyst adhere almost without getting into the fine pores of the catalyst to penetrate, there is no reduction in the catalytic activity; 2.) because the Catalyst is activated by the discharge, the denitration rate resp. speed improves, thereby increasing the life of the catalyst is increased; 3.) the atom, the excited molecules and the like., As a result of the discharge also improve the denitration rate.

The invention is described below with reference to the accompanying Drawings explained in more detail. They show: FIG. 1 a typical one in schematic form Example of conventional electrostatic precipitators; Fig. 2 in a schematic Form the principle of the electrostatic precipitator according to the invention; Fig. 3 in In the form of a diagram, the structure of the electrostatic precipitator according to the invention, by cycling the particulate insulator; 4 in schematic form Form an embodiment of the invention in which equilateral angle iron as electrodes be used; and Fig. 5 various other examples of the shape of the cross section of the electrodes which can be used according to the invention.

The electrostatic precipitator of the present invention is described below explained in more detail with reference to the accompanying drawings, but without this to be limited.

In Fig. 2, a high-voltage electrode 9 consists of line electrodes, needle-shaped electrodes or electrodes in the form of a rod, the cross-section of which is triangular, with all of these electrodes parts having a high electric field strength and it is connected to a high-voltage generator 11. The grounded Electrode 8 has a structure somewhat resembling a metal mesh and the like which gases can pass freely, but on which the particulate insulator 10 is withheld. When a gas containing dust flows in the direction of the arrow is left, the dust is due to the multipolar discharges of the particulate Insulator 10 in the vicinity of the high-voltage electrode 9 electrified and then on the surface of the particulate insulator spaced a distance from the High voltage electrode 9 has collected.

As a preferred embodiment, the practical implementation of the invention can be mentioned an example in which the particulate insulator 10 filled (packed) between two grounded electrodes 8 is, which are provided on both sides with a high-voltage electrode 9, the is located in the middle between the two grounded electrodes. When a such construction applied it is not beneficial from the standpoint of hazard prevention only, it is also extreme useful for transporting the particulate insulator.

The electrostatic precipitator according to the invention is shown in FIG described in more detail, which is used in Examples 1 and 2 described below will. In Fig. 3, the electrostatic precipitator contains a particulate Insulator 10, which is held between the grounded electrodes 8 and 8 ', by which the gases can flow freely through, with these electrodes above the smoke pipe 12 and the high-voltage electrode 9 are arranged by insulators 13 and 13 'embedded in the particulate insulator 10. These High-voltage electrode 9 is connected to a high-voltage generator (not in the figure shown) in connection and it becomes an alternating voltage, a direct voltage or a high frequency high voltage applied to it. In the middle section of the high-voltage electrode 9 with respect to the grounded electrodes described above a further grounded electrode 8 ″ is also provided, as shown in FIG.

Because the particulate insulator is transported through the entire device it can be expelled through the valve 19 and therefore it can, after the dust adhering to the particulate isolator by means of the vibrating sieve 20 has been removed by the conveyor 21 for reuse be fed back into the upper section of the device.

As concrete examples of a grounded electrode 8 and a high-voltage electrode 9 can also, as already mentioned, metal grid electrodes for the former and Lead electrodes or needle-shaped electrodes are used for the latter, however, one or both of the grounded electrode and the high-voltage electrode can also be used consist of a number of horizontally julousia-like rods, such as shown in Fig. 4, each having a substantially triangular cross-section has, as a result of which the following advantages are achieved: that is, if the grounded electrode 8 has a blind-like shape, becomes the discharge zone formed in the neighborhood of the vertical at the base of each triangle, thereby it is easier to electrify the dust particles, and the mechanical strength is high because it is not a thin wire like a metal mesh acts. If the high-voltage electrode 9 has a blind-like shape, can the packed materials on the upstream and downstream of the high voltage electrode 9 can be transported without mixing occurring, so that on the upstream side trapped dust particles can hardly get to the downstream side, causing it is possible, a respective independent dust collection on the upstream side and to be carried out on the downstream side. As a result, the rate or speed of the Dust collection can be further improved.

The shape of the cross section of the electrodes is from the point of view of FIG structural strength and the rate of dust collection viewed preferably triangular, it can but also different other electrodes with a cross section as shown in FIG. 5 can be used is.

The invention is illustrated in more detail by the following examples, but without being limited to it.

Example 1 In the device shown in FIG. 3, gravel sand was used with a particle diameter of 4 to 6 mm is used, its specific resistance 5 x 10 ohms x cm, and when applying an alternating voltage of 30 to 45 KV a current of 1 to 20 mA / m² was observed per surface of the grounded electrode.

An exhaust gas containing about 1.0 g / Nm³ of dust was blown at a surface velocity of about 40 cm / sec. introduced into the device and among those indicated above Conditions, the dust was collected, taking the effectiveness of the dust removal achieved Was over 99%. In this case, the particulate insulator was made with a linear Speed of 50 cm / sec. through the Vorricktuna "- circulated.

Example 2 In the same device as in Example 1 was used as particulate insulator uses a catalyst containing copper on an alumina support contained, with a particle diameter of 4 to 6 mm, whose specific resistance> 1013 ohms x cm was, and when an alternating voltage of 40 KV was applied a Current of 10 mA / m² per area of the grounded electrode was observed.

One containing 200 ppm NO, -1500 ppm ppm SO2 and 1.5 g / Nm³ dust Exhaust gas to which 250 ppm ammonia had been added was treated by making it at 3500C and with a surface speed of about 40 cm / sec. in these Device initiated. It was found that the effectiveness of dust removal was more than 99% and that the denitration rate was more than Was 95%.

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Claims (11)

Patent claims Electrostatic precipitator for dust removal, in which a gas bag containing dust is treated to remove the dust therefrom, in which the dust evolving gas passes through the spaces between two electrodes, to which a voltage is applied, filled particulate insulator passed is indicated by the fact that the particulate insulator (10) is used under such conditions that its apparent electrical resistance when filled is greater than 5 x 108 ohms x cm and that at least one of the electrodes (8, 9) is used in a state in which they are cut off is provided with a high electrostatic field strength therein. 2. Apparatus according to claim 1, characterized in that the Electrodes (8, 9) an alternating voltage is applied. 3. Apparatus according to claim 1 or 2, characterized in that at least one of the electrodes (8, 9) is covered with an insulator (10) and one AC voltage is applied. 4. Device according to one of claims 1 to 3, characterized in that that a DC voltage is applied to the electrodes (8, 9) under such conditions becomes that the apparent electrical resistance of the particulate insulator (10) higher than 5 x 108 ohms x cm but lower than 2 x 11 ohms x cm. 5. Device according to one of claims 1 to 4r, characterized in that that the particulate insulator (10) is transported through between the electrodes (8, 9) will. 6. Device according to one of claims 1 to 6, characterized in that that two grounded electrodes (8, 8 ') face each other and in the middle between them a high-voltage electrode (9) is arranged to form an electrode set and that the particulate insulator (10) is between the two grounded electrodes (8, 8 ') is filled. 7. Apparatus according to claim 6, characterized in that at least one of the grounded electrodes (8, 8 ') and the high-voltage electrode (9) has such a cross-section, the shape of which is sections with a high electric field strength and that these electrodes come in a variety of different heights are arranged horizontally at a vertical distance from each other. 8. Process for treating the dust collected from an exhaust gas, characterized in that a dust-containing gas is passed through the spaces a particulate insulator conducts, the one between 2 electrodes, to which a voltage is applied has been filled in so that the apparent electrical resistance of the particulate insulator greater than 5 x 108 ohms x cm the dust may be collected on the surface of the particulate insulator and that after taking out the particulate insulator on which the dust adheres, from the electric field the dust is stripped from the particulate insulator and is removed. 9. The method according to claim 8, characterized in that the Dust in the dust-containing gas by transporting a particulate one therethrough Isolator by the electric field in contact with the dust-containing gas the surface of the particulate insulator collects and that after removal the particulate insulator from the electric field for stripping and removal of the dust from the particulate insulator for reuse is introduced into the electric field. 10. Process for removing dust and denitration of a dust and exhaust gas containing nitrogen oxide, characterized in that after Mixing the exhaust gas containing dust and nitrogen oxide with ammonia gas to form the dust by passing the gaseous mixture thus obtained through the intermediate spaces a layer of a particulate insulator composed of a. Denitration catalyst consists, passes through it, the particulate Insulator so filled between two electrodes to which a voltage is applied that the apparent electrical resistance of the particulate insulator higher can be as 5 x 108 ohms x cm on the surface of the particulate insulator collects, at the same time denitration is carried out, and that one then the particulate insulator to which the dust adheres from the electrical Takes out the field and strips and removes the dust from the particulate insulator. 11. Procedure. according to claim 10, characterized in that the Dust by transporting a particulate insulator through the electrical Field in contact with an exhaust gas containing dust and nitrogen oxide on the surface of the particulate insulator collects, at the same time denitration is effected, and that one of the particulate insulator after taking it out the electric field to scrape and remove the dust therefrom, the particulate Re-introduces insulator into the electric field for reuse.