EP2352595A1 - Method for the electric deposition of aerosols and device for performing the method - Google Patents

Abstract

The invention relates to a method for depositing charged aerosols, wherein the aerosol is first deposited under the action of a space charge in a collector electrode through which a flow can pass. Then electric charges of the deposited aerosol are collected on the collector electrode to generate a high electric potential. Finally, the remaining aerosol emerging from the collector electrode is passed through the deposition zone with a high field strength. According to the invention, the invention also relates to a device for performing said method.

Description

 Process for the electrical separation of aerosols and device for

Implementation of the procedure

The invention relates to a multi-stage process for the electrical separation of net-charged aerosols using space charge effects.

Two-stage electrostatic precipitators have long been known (eg US 2,129,783, 26.7.1938) and are mainly used in air conditioning technology and for the separation of oil mist.

In the first stage, the aerosol particles are charged by a corona discharge between a usually wire-shaped spray electrode and a mostly plate-shaped collecting electrode and partially deposited, wherein the residence time between the electrodes for a complete separation of the aerosol is usually too short.

In the second stage, the now electrically charged residual aerosol passes between parallel, mostly plate-shaped deposition electrodes. Alternately every other deposition electrode is connected or grounded with high voltage, so that a strong electric field is applied between the deposition electrodes and the charged particles are attracted to one of the electrodes and deposited. In the second stage, there is no corona discharge, so that only a very low current intensity is required for the high-voltage supply.

In recent decades, a continuous development of the two-stage electrostatic precipitator has taken place, with some of these advancements to be delineated in relation to the present invention. It must be said that the process step of particle charging, which is the essential process in the first stage of the two-stage electrostatic precipitator, is not an integral part of the invention.

No. 4,861,356 describes a two-stage electrostatic precipitator in which the problem of electric flashover between the deposition electrodes is solved by providing first a movable compressed air nozzle for blowing out the interelectrode space and secondly a very high impedance resistor between the high voltage supply and each one of the high voltage to be set to deposition electrodes is provided. This ballast is realized according to the invention by a corona discharge between a standing under high voltage tip or wire electrode and the plate to be electrified. To this end, the plates to be electrified protrude slightly (0.25 inches = 6.5 mm) from the grounded plates.

US 4,264,343 describes a two-stage electrostatic precipitator arrangement in which there are parallel, grounded, grounded collecting electrodes. The first stage is realized by high voltage, double pointed discharge electrodes, one of the two tips being directed at the second stage electrified separation electrodes. However, these deposition electrodes are each enveloped by a dielectric insulating layer and each separately connected to a high voltage power supply. Therefore, the discharge electrodes have no function for adjusting the potential of the deposition electrodes. The use of space charges for the separation of electrically charged aerosol particles is not fundamentally new either.

US 4,029,482 describes a separator in which aerosols are first charged by a corona discharge and then pass through a fiber filter or a porous bed of an electrically insulating material. In this case, the space charge effect causes electrical forces on the aerosol particles, which move them transversely to the flow and deposit them in the filter. Particulate separation is significantly increased compared with the use of a non-insulating filter material.

DE 101 32 582 describes an electrostatic precipitator in which the previously electrically charged aerosol is guided for deposition through a bundle of tubes arranged in parallel flow direction. The tubes are sprayed with water and therefore are grounded regardless of the choice of material through contact with the wall of the apparatus. It is proposed the use of tubes with differently structured inner surfaces and with spiral internals. Again, the deposition is mainly due to the space charge effect in the tubes, which is not explicitly mentioned. The deposition is further improved by a downstream filter.

The known technical solutions for the use of space charges for the separation of aerosols have some serious disadvantages, which results from the unfavorable, the physics of space charges disregarding constructions:

If one considers the electric field strengths which arise in a flow-through tube or in a filter through which the space charge flows, then with E the electric field strength, A the surface and V the volume content of an aerosol volume, εor dielectric constant, pi the space charge density:

This means, first, that with a uniformly distributed space charge density, the electric field strength increases linearly outward from the central axis or the center of the tube or filter. In contrast, the field strength in the middle of the tube or the filter is very low, so that the charged aerosol particles here experience no electrical forces and are therefore not separated. Thus, there is a partial flow of the aerosol in both of these constructions, which passes through the center of the assembly with virtually no separation.

Secondly, according to today's standards, very high deposition efficiencies of 99% and more are generally required, so that the aerosol concentration and thus the space charge density over the course of the aerosol through the tube or the filter layer would have to decrease accordingly. With decreasing space charge density, however, the resulting field strength decreases proportionally. Therefore, the volume flow of particles deposited in a pore under the action of the space charge (for a given charge of the individual particles) is proportional to the square of the particle concentration. It is therefore obvious that it is not possible to achieve sufficiently low aerosol concentrations in the clean gas with reasonable expenditure on equipment.

It is therefore the task of fundamentally improved and significantly improved for the deposition of aerosols by an improved design principle, the space-charge-based deposition.

The object is achieved by a method having the features of claim 1.

The invention is based on the assumption that the aerosol is already charged unipolar by an upstream process, for example a corona discharge or a conventional electrostatic precipitator. However, a suitable, not necessarily unipolar charging can also be generated by other processes, eg by a pneumatic transport or dry shredding. The decisive factor is that the aerosol carries a net charge, at least in total.

The basic idea is as follows:

First, in a first step, a large amount of charge is accumulated by the space charge deposition of a part of the aerosol. This first step is preferably performed in an electrically conductive hollow body, the collector electrode (CE), because doing the delivery of aerosol charges by deposition on the wall of the collector electrode (analogous to a Faraday cup) not by the already reached electrical potential of the collector electrode is influenced or hindered. Technically suitable realizations of a hollow body are, for example

a flow-through tube open on both sides, two (or more) parallel, electrically interconnected plates, through whose space the aerosol flows through unilaterally open cups or bells into which the aerosol is blown

Hollow body of the type described above with perforated walls

Perforated plate, sieve cloths, loose material etc. cylindrical or plate-shaped parts of a bulk volume through which the aerosol flows.

The space charge of the aerosol currently contained in the collector electrode and the charge of the aerosol particles deposited in the collector electrode together produce a very high, with time still increasing, electric potential of the collector electrode.

The second step is to use the accumulated charge amount to create a strong electric field in which residual aerosol, which is still carrying electrical charges but too low concentrated for efficient space charge deposition, can be deposited. Also for this there are different variants:

the collector electrode is electrically conductively connected to a downstream field electrode (FE), the field is formed between the field electrode and one or more precipitation electrodes (NE), the collector electrode acts as a field electrode, by the residual aerosol between the outside of the collector electrode and a grounded collecting electrode or a grounded housing is passed.

The electrically conductive, compared to the housing of the system but isolated hollow body (the collector electrode) can be replaced in many cases without significant loss of function by a non-conductive hollow body, when the residual aerosol to be deposited in the second step again directly to the collector electrode with the contained and deposited space charges can be passed. This is therefore always the case when collector electrode and field electrode are spatially combined according to the second of the above variants.

Since the space charge-related deposition of the charged aerosol particles in the collector electrode continues to run independently of the potential of the collector electrode, the collector electrode can reach extremely high electrical potentials of 100 kV or more, which otherwise can only be generated by expensive high-voltage generators. On the other hand, it would inevitably come after a certain period of operation to flashovers between the collector electrode and the grounded system housing. In this case, due to the very high electrical conductivity of the flashover channel, a complete discharge or even (due to the induction effect) would lead to a temporary transfer of the collector electrode. In addition, it could cause damage to the device and the emission of electromagnetic interference pulses. Therefore, the invention provides a device which limits the electric potential of the collector electrode to a value well below the breakdown voltage. Particularly suitable for this appears a corona discharge path, the insensitive and is very simple, and the discharge voltage (Corona threshold voltage) can be set in a wide range. The corona discharge path can be located either outside the separation space (eg at the high voltage insulators for the suspension of collector electrode and field electrode) or also inside the separation space (ie between collector electrode or field electrode and grounded housing wall). The latter has the advantage that the current flowing through the corona can be used again for additional charging of the aerosol at the entrance to the second stage. However, variations in the temperature or gas composition of the gas to be purified can then also lead to fluctuations in the potential at the collector electrode.

If the collector electrode / field electrode is to be operated at very high potential values, then it may be useful to connect the corona discharge path through a corona cascade, i. to replace a cascade of individual corona discharge paths.

Also for the cleaning process, the special operation of the autogenous space-charge-based deposition (ARA) must be taken into account. There is a risk that it comes through the cleaning to a potential equalization between the collector electrode / field electrode and the earth, or that aerosol that has released its charges at the collector electrode, gets back into the flow. The autogenous space charge-supported deposition is therefore particularly suitable for the separation of liquid aerosols which run off the collector electrode. However, solid aerosols can also be separated off and cleaned off the collector electrode by liquefying and removing the dust layer on the collector electrode from time to time or continuously by means of a liquid spray introduced into the aerosol. In addition, other Abreinigungsarten, such as cleaning with a compressed air jet, conceivable. In addition, the suspension insulators of the collector electrode / field electrode or via insulating impact hammers can also be subjected to mechanical cleaning by transmission. tion of force pulses. In this case, a possible aerosol discharge by blocking the aerosol flow during cleaning can be prevented.

Overall, the efficiency of the process depends critically on the quality of the insulation and on the fact that the aerosol-borne electrical current is sufficiently high to compensate for the charge drainage via the insulators, the collector electrode and the field electrode. Therefore, this method is particularly suitable for use directly behind the place of charge generation (corona charging, electrically assisted atomization, mills, etc.). At low or highly fluctuating aerosol concentrations, a highly charged auxiliary aerosol can be generated (e.g., by electrical atomization of a liquid) to bring sufficient current to the field electrode.

Further features, details and advantages of the invention will become apparent from the illustrated with reference to the drawings embodiments.

FIGS. 2 to 5 show different implementations of the basic idea.

Figure 2 shows a particularly simple, preferred construction for the purification of small and medium volume flows. A part of the inflowing, electrically charged aerosol 1 flows through the tubular collector electrode 3 and is again partially deposited in this. The electric potential accumulated on the collector electrode by the particle precipitate generates high electric field strengths between the collector electrode 3 and the precipitation electrode 5. Thus, the aerosol flowing between the collector electrode and the precipitation electrode is well cleaned already in the first stage, while the partially purified gas leaving the collector electrode 10 contains even higher particle concentrations. In order to also completely clean this aerosol, the high potential of the collector electrode 3 is transmitted to the field electrode 4 through a conductive connection 11. The incompletely cleaned aerosol in the first stage is now exposed to the high field strength between the field electrode and the collecting electrode 5 in the second stage and occurs as Clean gas 2 out of the separator. The collecting electrode 5 is here at the same time the housing 18th

Figure 3 shows a particularly compact construction, which appears suitable especially for small volume flows. The second purification stage is realized here by an aerodynamic recycling of the aerosol. In this case, collector electrode 3 and field electrode 4 are combined in one electrode. The charged crude aerosol 1 enters the apparatus through a nozzle 15 as a propelling jet at high speed, so that the partially purified aerosol 10 flows back through the space between the field electrode and the housing. To ensure a safe function, a part of the clean gas 2 is to be recirculated into the raw gas stream.

Comparable is the operation of the separator according to FIG 4. Even with a mixture of raw gas 1 and partially purified aerosol 10 inside the designed as a bell-shaped mixing container collector electrode / field electrode 3, 4 creates a sufficiently high potential, which then leads to a very high deposition in the outer space between Mixing tank and housing 18 leads. In addition, here corona tips 20 are shown on the outside of the bell over which limits the potential to avoid flashovers. The corona can be used here for further charging of the aerosol. Seperated liquid aerosol can flow off via a drain opening 7.

FIG. 5 shows an embodiment similar to FIG. But here the charged aerosol flows through the collector electrode / field electrode 3, 4. The discharge of the collector electrode / field electrode takes place in this case with the aid of a corona discharge cascade 25.

FIG. 6 shows a preferred design for the purification of large aerosol volume flows. The collector electrode / field electrode consists of a larger number, for example 4 plates 3, 4, which are electrically connected to each other to compensate for any potential differences. In the upstream part of the separator, these plates act as collector electrodes passing through the charged one Roha aerosol 1 will be charged. In the downstream part of the separator, the plates act as field electrodes with respect to the interposed precipitation electrodes 5. Also opposite the housing 18, the plates 3, 4 act as field electrodes, so that the gas passing between the plates and the housing is completely freed from the charged aerosol particles , Due to the accumulated charges, a strong electric field is generated between the collector electrode / field electrode 3, 4 and the collecting electrode 5.

Another possibility is to use a non-conductive packing as a collector electrode / field electrode. FIG. 7 shows a structure where a cylindrical packing is flowed through from the inside. The insulating piece of pipe 3, 4 acts as a collector electrode and at the same time as a field electrode which generates a high electric field strength in the non-conductive packing 12. The packing offers the advantage that the particles to be separated have only a short way to cover a surface. Instead of a packing, it is also possible to use a bed of non-conductive packing or an arrangement of concentric pipes.

Figure 1 shows a not falling under the invention arrangement.

In Figure 1, the charged aerosol 1 flows through an array of 3 concentric cylinders. In the innermost cylinder deposition takes place only by the effect of the space charge, whereby a high charge density accumulates on the outside of the cylinder. This results in the space between the innermost and the middle cylinder, a high field strength, is deposited by the aerosol on the inner wall of the middle cylinder. Likewise, there is an increased separation between the middle and the outer cylinder through the field of the middle cylinder. The disadvantage of this very simple arrangement is that the aerosol flowing through the inner cylinder is exposed to only low field strengths and is therefore only imperfectly deposited.

Claims

Process for the electrical separation of aerosols and device for carrying out the process

1. A method for separating charged aerosols into a two-stage electrostatic precipitator having at least one collector electrode and at least one field electrode,

characterized by the following steps:

Partial separation of the aerosol in the flow-through collector electrode under the effect of the space charge,

Collecting the electrical charge of the deposited aerosol to generate a very high electric potential on the collector electrode, optionally transmitting the electric potential to a field electrode and Passing the residual aerosol leaving the collector electrode through the high field separation zone formed between the collector electrode and / or the field electrode and a grounded precipitation electrode.

2. The method according to claim 1, characterized in that the collector electrode and / or field electrode is cleaned with liquid.

3. The method according to any one of claims 1 or 2, characterized in that the discharge of the collector electrode and / or field electrode is controlled.

4. The method according to claim 3, characterized in that the controlled discharge of the collector electrode and / or field electrode takes place by means of a corona-negative cascade.

5. The method according to any one of claims 1 to 4, characterized in that an auxiliary aerosol is used for the delivery of charge.

6. The method according to any one of the preceding claims, characterized in that a second purification stage is realized in that the aerosol is returned aerodynamically.

7. A device for carrying out a method according to one of claims 1 to 6 with a collector electrode, a flow-through field electrode and a grounded precipitation electrode, characterized in that a deposition zone with high field strength between the collector electrode and / or the field electrode and a grounded precipitation electrode is formed ,

8. The device according to claim 7, characterized in that the collector electrode and / or field electrode is designed in plate construction.

9. Apparatus according to claim 7, characterized in that the collector electrode and / or field electrode is designed in Rphrbauweise.

10. Device according to one of the preceding claims, characterized in that the collector electrode and / or field electrode is associated with a nozzle, via which the charged Rohaerosol can be passed as a driving jet at high speed in the direction of the collector electrode and / or field electrode.

11. The device according to claim 10, characterized in that the collector electrode and the field electrode are combined in one electrode.

12. The device according to claim 9, characterized in that the collector electrode and / or field electrode is designed in mixing container design.

13. Device according to one of claims 7 to 12, characterized in that the collector electrode and / or field electrode is conductive.

14. Device according to one of claims 7 to 13, characterized in that the collector electrode and / or field electrode is not conductive.

15. The device according to claim 7, characterized in that a non-conductive packing is used as a collector electrode and / or field electrode.