EP1679123A1 - Process and apparatus for electrical charging and separation of hardly removable particle - Google Patents

Abstract

The method involves using only one high voltage source (1) to ionize particles successively in the high voltage zone and removing the particles and producing a significantly higher flow in the ionization region (4) than in the separation region (5) by suitable selection of the negative electrode geometry for the ionization and separation region.. The particles are ionized and separated with negative electrodes (7) connected to only one output for the separation of dust from industrial gases both in the ionization regions of the individual gases as well as in the separation region. An independent claim is also included for a device for implementing the inventive method.

Description

The invention relates to a method and apparatus for electrostatic charging and deposition of difficult to be separated particles of a gas fluid according to the preambles of independent claims 1 and 5. It is in other words an electrostatic precipitator and an electrostatic precipitator.

In the working according to the so-called Cottrell principle electrostatic precipitator for dedusting industrial emissions, which can also be referred to as Elektroabscheidevorrichtungen, it is known to charge and transport the deposited particles and their attachment to optionally specially shaped precipitation electrodes simultaneously in an electric field, the particles after sufficient Accumulation or agglomeration either by mechanical vibration (dry cleaning) or by rinsing (wet cleaning) are removed from the collecting electrode. If necessary, several of the above-described electric fields are connected in series or in parallel in order to achieve the desired overall separation efficiency.

The reason that some particles are difficult to separate may be due to the electrical properties of the particles, which due to their chemical-physical nature at the collecting electrodes result in an insulating layer. In addition, due to the electric flow turbulence or the so-called electric wind at high current density as a result of Gasionisierung in the area between the charging and deposition electrodes in particular the proportion of particles in the grain <10 microns is increasingly difficult to accumulate on the collecting electrodes. It is known that as a result of the physically effective charging mechanisms, namely the so-called shock or field charging and the diffusion charging, a more or less pronounced minimum of the particle fraction separation efficiency occurs. In order to counteract the problems of electric flow turbulence as a result of the electric wind, so-called two-stage electrostatic precipitators have also been used developed, in which charge and deposition of the particles in successively connected separate electric fields. The spatially necessary separation of the stages and their different electrical high voltage supply is problematic.

In order to solve these problems, the Applicant has already developed electrostatic precipitators for dedusting industrial waste gases which operate with a negative spray system. In particular, it has proposed a method in which particles which are difficult to deposit are removed from a gas fluid with the aid of electrostatic charging and deposition by means of only one high voltage source for a high voltage zone, wherein the particles within the high voltage zone successively and not simultaneously, in contrast to the so-called Cottrell electrostatic precipitators be ionized and separated. In addition, in this method or in the devices for carrying out the method in the ionization region, a larger geometric gap is set than in the deposition region, as a result of which the field strength of the ionization region is smaller than the field strength of the deposition region. As a result, the applicant has succeeded in its filtering process to avoid the disadvantages of electrical turbulence as far as possible.

From the prior art similarly functioning air filters are also known for the purification of breathing air, which are intended in particular for use in households, restaurants and lecture halls. Air filters and industrial filters, however, are not comparable because air filters must meet completely different requirements than the large industrial electrostatic precipitators involved, and therefore they can not be used to clean industrial gases.

Air filters are also known, each working with a positive spray system and two high voltages. These air filters have a rectifier with two outputs for ionization and separation. The field strengths in the known air filters are the same in the ionization and deposition area, but provided with different voltage potentials. Both areas must be carried out electrically isolated from each other. In addition, in the known filters in the ionization region positive discharge electrodes are provided, which cause a moderate ionization.

Against the background of the ever increasing demands on the energy efficiency of industrial plants, the invention has the object to avoid the disadvantages of the above-described electrostatic precipitator and electrostatic precipitator method and to reduce the energy consumption in the filtering of industrial emissions.

The solution of this object succeeds according to the invention with the method according to claim 1 and the device according to claim 5. Preferred developments of the method and the device are described in the subclaims.

The separator according to the invention and the deposition method according to the invention thus work with a negative spray system in which a just sufficient charge of the particles is carried out with the aid of only one high-voltage source in each high-voltage zone. Accordingly, the transport of the charged particles and their deposition takes place with the least additional energy expenditure on the oppositely poled precipitation electrodes, the individual passages known from the conventional filters having a negative spray system being left unchanged.

This means that a region of extreme ionization with a correspondingly high electrical turbulence or electric wind across the gas flow is followed by a substantially calmed virtually laminar region, essentially without electrical turbulence, in which the deposition of the charged particles which are difficult to deposit can take place in a highly efficient and unhindered manner.

The efficient and as complete as possible charging of the particles is carried out at an applied high voltage in the ionization region, which in turn generates a field strength in the subsequent deposition area with the lowest current flow, which is sufficient for transport and deposition of the particles.

This is realized in principle for various electrostatic filter embodiments in that in the individual lanes of the high-voltage zone with unchanged lane spacing extremely different physical spraying distances in the ionization and in the separation area by strongly current-intensive or strongly current-suppressing electrode forms at a common high voltage source are used, as far as possible the principle of the larger geometric spray distance in the ionization region and the lower geometric spray distance in the separation region is set.

Optionally, multiple ionization and deposition sections within an electrostatic filter field may be sequentially arranged if the single particle charge is insufficient.

Fig. 1

das allgemeine Partikel-Abscheideverhalten in einem Elektrofilter;

Fig. 2

Beispiele des typischen elektrischen Kennlinienverhaltens der Negativ-Elektrodenformen für den lonisationsbereich und den Abscheidebereich des erfindungsgemäßen Verfahrens;

Fig. 3

eine Übersichtsanordnung eines ersten Ausführungsbeispiels einer einzelnen Abscheidegasse der erfindungsgemäßen Abscheidevorrichtung;

Fig. 4

eine Übersichtsanordnung eines zweiten Ausführungsbeispiels einer einzelnen Abscheidegasse der erfindungsgemäßen Abscheidevorrichtung;

Fig. 5

ein erstes Ausführungsbeispiel eines erfindungsgemäßen Elektrofilters mit zwei Abscheidegassen und einem lonisierungsbereich;

Fig. 6

ein zweites Ausführungsbeispiel eines erfindungsgemäßen Elektrofilters mit drei Abscheidegassen und zwei lonisierungsbereichen; und

Fig. 7

ein drittes Ausführungsbeispiel eines erfindungsgemäßen Elektrofilters mit zwei Abscheidegassen mit gekühlten Niederschlagselektroden im Ionisierungsbereich.

For explanation, several embodiments of the invention will be described in more detail with reference to figures and diagrams shown in the drawing. In it show schematically:

Fig. 1

the general particle separation behavior in an electrostatic precipitator;

Fig. 2

Examples of the typical electrical characteristic behavior of the negative electrode forms for the ionization region and the deposition region of the method according to the invention;

Fig. 3

an overview of a first embodiment of a single separation gate of the separation device according to the invention;

Fig. 4

an overview of a second embodiment of a single separation gate of the separation device according to the invention;

Fig. 5

a first embodiment of an electrostatic precipitator according to the invention with two Abscheidegassen and a lonisierungsbereich;

Fig. 6

A second embodiment of an electrostatic precipitator according to the invention with three Abscheidegassen and two ionisierungsbereichen; and

Fig. 7

a third embodiment of an electrostatic precipitator according to the invention with two Abscheidegassen with cooled collecting electrodes in the ionization region.

Fig. 1 shows the particle separation behavior in an electrostatic precipitator. As a result of the physically effective charging mechanisms, namely the so-called impact or field charging and the diffusion charging, a more or less pronounced minimum of the particle fraction separation efficiency occurs. This can be clearly seen in each of the curves shown.

FIG. 2 shows how far the individual characteristics of the negative electrode geometries in question must differ so that the objective according to the invention can occur. The characteristics in the left-hand part of the diagram correspond to the strongly current-collecting electrode forms (A, B and C type) for the ionization region, while the characteristics shown in the right-hand part of the diagram correspond to the current-poor electrode shapes (D, E and F type) for the deposition region correspond.

Fig. 3 shows the overview of a single Abscheidegasse with the working sections ionizing and deposition. Neighboring analogue streets are not shown. To a high voltage power source 1, a high voltage system 2 is connected, which is provided with power-intensive discharge electrodes 6 and voltage-intensive or low-current negative electrodes 7. The spray electrodes 6 are located in an ionization region 4, which is formed by the grounded collecting electrodes 3. The negative electrodes 7 are located in a deposition region 5, which is likewise formed by the precipitation electrodes 3. 11 marks the entire high-voltage zone. In ionization region 4, also referred to as ionization region, there is sufficient charge of the particles achieved, which are then optimally deposited in the following separation area 5 with greatly reduced turbulence or almost missing electrical wind.

If the one-time particle charging in a high-voltage zone is not sufficient for optimum deposition, a further ionization region 4a can be connected downstream of the ionization region 4 and the deposition region 5 with a deposition region 5a according to FIG.

Fig. 5 shows a schematic representation of a horizontally arranged electrostatic precipitator, a so-called horizontal field. Here, a plurality of rows of collecting electrodes 3 are provided within a filter housing 8 with the ground 12, which form several Abscheidegassen 13, which in turn have a lonisationsbereich4 with the power-intensive discharge electrodes 6 and a deposition area with low-current negative electrodes 7. The embodiment shown here has two Abscheidegassen 13, but more Abscheidegassen 13 can follow, as indicated by the dashed lines 14.

FIG. 6 shows a further exemplary embodiment of the electrostatic precipitator according to the invention, wherein two ionization regions 4 or 4a and two deposition regions 5 and 5a are arranged within the three separation trays 13 shown. Moreover, the negative electrodes 7 having an elliptic shape shown in Fig. 6 have another candidate geometry.

FIG. 7 shows a third exemplary embodiment with an ionization region 4 in which the precipitation electrodes 9 which are earthed with 12 are designed as hollow bodies (cooling chamber 10) through which a coolant 9 flows. With this cooling, a back ionization, also referred to as back-spraying, due to an extreme electrical resistance of deposited particles in the ionization region 4 is avoided.

With the schematic diagrams of the essence of the invention is clearly shown, namely within a high voltage zone 11 in their unmodified Einzelgassen 13 with only one high voltage power source 1 optimal electrical charge or ionization in the ionization 4, 4a perform and subsequent particle deposition in the separation region 5, 5a with sufficient To ensure field strength.

Claims (9)

A method in which by means of the electrostatic charging and deposition by means of only one high voltage supply source for a high voltage zone difficult to be separated particles are removed from a gas fluid, wherein the particles are ionized and deposited successively within the high voltage zone with constant lane width and by suitable choice of the negative electrode geometry for ionization - and deposition region in the ionization a significantly higher current flow than in the deposition area is generated,
characterized,
that for the separation of dusts from industrial gases, the particles are ionized and separated both in the ionization region of the individual lanes and in their deposition area by contiguous, connected to only one high voltage power source with only one output, negative electrodes. Method according to claim 1
characterized,
that the particles within the individual streets of the high-voltage zone in a kind of series connection are ionized and separated two or more times in succession. Method according to one of claims 1 or 2
characterized,
that the particles of the fluids to be cleaned within the individual lanes are charged by the applied negative high voltage in the ionisierungsbereichen with at least 10-fold flow of current to the Abscheidebereichen. Method according to one of claims 1 to 3,
characterized,
that the earthed electrodes are cooled the lonisierungsbereiches. Device for carrying out the method according to one of claims 1 to 4, in an electrically operating filter having a high-voltage zone with individual lanes, which have an ionization region, each having a downstream deposition region,
in
by a filter for separating dusts from industrial waste gases, the filter having one or more high-voltage zones, each of these zones being provided with a high-voltage supply source and wherein both the ionization regions (4) and the deposition regions (5) are each provided with different negative electrodes (6 , 7) connected in series to a high voltage power source (1) having only one output. Device according to claim 5,
characterized,
in that the negative electrodes in the ionization regions (4) and the deposition regions (5) are formed by suitable geometrical design such that an at least 10-fold spray current is produced in the ionization regions (4) with respect to the deposition regions (5). Device according to one of claims 5 or 6,
characterized,
that the geometries of the negatively polarized electrode (6, 7) for the ionization (4) and the separation region (5) are designed differently, with low-current largely for the ionization zone (4) high power-intensive Sprühelektrodenformen (6) and for the separation zone (5) or voltage-intensive negative electrode forms (7) are used. Device according to one of claims 5 to 7,
characterized,
that are arranged in a high voltage zone in the individual lanes several lonisierungsbereiche (4, 4a) and Abscheidebereiche (5, 5a) in the direction of flow of the fluids in a row. Device according to one of claims 5 to 8,
characterized,
that the collecting electrodes are provided with cooling chambers (10) (9) of lonisierungsbereiches (4).

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