WO1998022223A1 - Corona electrodes for a filter structure for separating impurities from a flow of gas, filter structure with corresponding corona electrodes and method of operation - Google Patents

Abstract

To homogenize the electric field in the filter channel, that is defined by two precipitation electrodes (1), of a filter structure for the separation of dustlike or drop-shaped impurities from a flow of gas, corona electrodes (3) are used. These are plate formed - e.g. designed with a central plate (5a) and with edge plates (5b) projecting on opposite sides and joining front and back in an obtuse angle - and have, on the front and back edge, an in each case continuous area of curvature (6) produced by beading, with a radius of curvature of 2-5 mm. The areas of curvature show, throughout their length, an approximately uniform curvature and constitute the laterally most protuberant parts. By the average distance of consecutive areas of curvature (6) and the formation of the same, the production of charge carriers for electrostatic cleaning can be controlled and, in particular, overproduction of the same, which favours back spray, can be prevented. Corona formation occurs exclusively during voltage impulses and only at the areas of curvature (6).

Description

 Corona electrode for a filter arrangement for separating contaminants from a gas stream, filter arrangement with corresponding corona electrodes and method for their operation

The invention relates to a corona electrode for a filter arrangement for separating contaminants from a gas stream, a filter arrangement with corresponding corona electrodes and a method for operating the same.

It has long been known to dedust gases, especially from incineration plants, in electrostatic filter arrangements. The gases are passed through filter lanes, usually about 30-40 cm wide, which are delimited on both sides by plate-shaped separation electrodes. Corona electrodes are arranged approximately in the middle of each filter lane between the separating electrodes. A DC voltage is placed between the same and the separating electrodes, which is overlaid by short voltage pulses of the same polarity. The corona electrodes are negatively polarized. During the voltage pulses, the voltage may e.g. B. be about 1.5 times the DC voltage. The repetition frequency of the voltage pulses today is usually 10 to 100 Hz, the length of which is approx. 100 μs. However, shorter pulse lengths down to approximately 10 μs have also been proposed (G. Trebbi, BG Padera: 'Pulse energization; a new look at an attractive technology for upgrading ESP Performance ¹ , Proc. Ann. Power Conf. 57-1 (1995), pp. 785-792). During the voltage pulses, corona discharges form on the corona electrodes, through which charge carriers emerge and form negatively charged ions that attach to dust particles. The dust particles thus charged migrate under the effect of the forces exerted on them by the electric field against the positive separation electrodes, where they accumulate as filter dust. Periodically, the separating electrodes are mechanically vibrated, as a result of which the filter dust comes off and falls into a collecting trough, from which it flows e.g. B. is transported away by means of a screw.

A filter arrangement of the structure described is e.g. B. known from the brochure S. Matts: 'Fläkt Electrostatic Precipitators' from ABB Asea Brown Boveri. The corona electrodes are designed there as straight wire helices.

Certain typical difficulties arise with generic filter arrangements. One of them is the so-called back spraying. Since the charge of the deposited filter dust must continue to flow to the separating electrode - the

Electricity increases with the separation capacity - filter dust with a high specific resistance (> 10 Ωcm), such as occurs especially when burning low-sulfur coal, leads to very high field strengths in the dust layer, which can lead to breakdowns and the formation of positively charged ions. The migration of such ions - under the effect of the forces exerted on them by the electric field from the deposition electrode to the corona electrode - leads to the neutralization of negatively charged particles and has an effect Separation of filter dust at the separation electrodes. The risk of back spraying thus limits the field strength to which the dust layer may be exposed and thus the current density through the dust layer and thus ultimately the separation performance of the filter arrangement.

The risk of back spraying is particularly great when there is locally an excess of charge carriers produced by corona discharges. The occurrence of such an excess is affected by the pulsed supply as it was developed for this and other reasons (see BHJ Hall: 'History of pulse energization in electrostatic precipitation', Journal of Electrostatics 25 (1990), pp. 1-22), contrary, but with the known wire-shaped corona electrodes it is hardly possible to solve this problem without undesirable side effects.

With a relatively large distance between successive wire-shaped corona electrodes, the electric field is very inhomogeneous. Since the permissible peak values of the field strength are limited by the risk of back spraying, it drops to relatively low values between two successive corona electrodes. However, in the interest of high separation performance, the average electric field in the filter lane should be as high as possible.

However, the average field strength is primarily limited by the fact that, in the case of high-resistance dusts at the corona electrodes, where the field strength is greatest, there are no corona discharges between the voltage pulses become. Corona formation should only occur during the voltage pulses if possible.

A high density of corona electrodes leads to a more homogeneous field, but too many charge carriers are generated during the voltage pulses, which, as already mentioned, favors the back-spraying.

To solve these problems, experiments were also carried out with corona electrodes other than wire-shaped. Experiments were carried out with plate-shaped corona electrodes, which were provided with spikes arranged in a certain regular pattern to generate corona discharges (see PJ McKinney, JH Davidson, DM Leone: 'Current Distributions for Barbed Plate-to-Plate Coronas', IEEE Transactions on Industry Applications 28/6 (1992), pp. 1424-1431). Although this leads to a large-scale homogeneous electric field in the filter lane and also allows the production of charge carriers to be adjusted via the arrangement and formation of the spikes, the field in the vicinity of the corona electrodes is very inhomogeneous, so that certain flow trajectories from the formation of the corona and the resulting charging of the particles can hardly be detected and the gas flow there is practically not subjected to cleaning.

From DE-A-1 407 503 it is known, in the case of plate-shaped deposition electrodes and, in parallel therewith, corona electrodes arranged between them, for the purpose of mechanical reinforcement, to strip edge strips off to one side at an obtuse angle and then to the opposite side at an acute angle Form the electrode in the direction of the reinforcement strips. At the free edges they each have a further acute-angled bend directed towards the electrode. Triangular spray flaps are punched out at intervals on the two cylinder sector-shaped curvature zones, which lie in the plane of the reinforcement strip normal to the plane of the electrode and project laterally beyond the curvature zones. With this arrangement, corona formation does not occur at the zones of curvature but at the spray lobes. The forming the zones of curvature

Bends only serve to mechanically reinforce the electrode by means of angled reinforcement strips, that is to say not by weld seams connected to it.

A similar assessment is made of US-A-3,200,566. In this document, the corona electrodes are each designed as a flat rectangular plate which, for stiffening, has round flanges at its edges or obtuse-angled and then acute-angled profile strips which each extend over their entire height and form a narrow convex zone of curvature. The flanges or profile strips each have press-made, vertically spaced, laterally projecting wart-like projections of approximately hemispherical shape and a larger curvature, on which the corona formation is to occur above all.

The invention is intended to remedy this. The invention, as characterized in the claims, creates a corona electrode with which it is possible to maintain a homogeneous electric field in the filter lane and at the same time to produce charge carriers on the limit the desired extent. This option is used as advantageously as possible in the filter arrangement according to the invention, in particular if it is operated in accordance with the method according to the invention.

The advantages achieved by the invention are primarily that the high average field strength in the filter lane exerts large forces on the particles to be separated and the particles are transported at high speed against the separation electrodes, so that a high transport and separation performance is maintained. Thanks to the homogeneity of the field and the absence of strong local elevations, the average field strength can be approached relatively close to the limit, which leads to breakdowns in the dust layer or in the gas space. The formation of corona and thus the production of charge carriers can be largely independent of that by specifically arranging zones of curvature, in which corona formation occurs preferably only and exclusively during the voltage pulses

Formation of the electric field in the filter lane can be set to desired values. Overall, a very high performance of the filter arrangement can be achieved by pushing back factors which favor the back spraying. Due to the continuous formation of the curvature zones over the entire height of the corona electrodes, all flow trajectories are also completely captured by the cleaning mechanism. The invention is explained in more detail below with reference to figures which merely represent exemplary embodiments. Show it

1 shows a longitudinal section through the flow direction of the gases through part of a filter lane of a filter arrangement according to the invention with corona electrodes according to the invention according to a first embodiment,

2a shows the electrical potential between a corona electrode according to the first embodiment and a deposition electrode when a DC voltage is applied,

Fig. 2b the electrical potential between one

Corona electrode according to the first embodiment and a deposition electrode when applied

DC voltage, superimposed by a voltage pulse and the corona discharge caused thereby,

Fig. 3 shows a longitudinal section through part of a filter passage of a second inventive

Filter arrangement with corona electrodes according to the first embodiment according to the invention,

4 shows a longitudinal section through part of a filter lane of a filter arrangement according to the invention with corona electrodes according to a second embodiment according to the invention and 5 shows a longitudinal section through part of a filter lane of a filter arrangement according to the invention with corona electrodes according to a third embodiment according to the invention.

The filter arrangement according to the invention (FIG. 1) has a plurality of separation electrodes 1, which are at a distance of, for. B. 40 cm are arranged side by side and z. B. consist of three 5 m high stacked steel plates. Two adjacent separating electrodes 1 form between them a filter lane 2, through which a gas stream loaded with ash or other dust-like or droplet-like impurities is passed in the direction of the arrow. Successive corona electrodes 3 are arranged in the center of the filter alley 2. The same extend over the entire filter lane 2. Their height is therefore 15 m in the example described, although they can of course be composed of several sections like the separating electrodes 1.

Between the separating electrodes 1, which can be grounded, on the one hand, and the corona electrodes, on the other hand, a DC voltage is applied by means of a high-voltage generator 4, which, for. B. can be 60 kV. This DC voltage is at a repetition rate, which, for. B. between 10 and 100 Hz and preferably not above 20 Hz, of short, z. B. superimposed about 10 to 100 μs voltage pulses, which have a peak value of, for example, 26 kV, so that the voltage reaches peak values of 86 kV overall. The DC voltage is chosen so that it is high electric field generated in the filter lane, but does not lead to corona formation on the corona electrodes. The corona electrodes 3 always form the negative pole.

The corona electrodes 3 are as flat rectangular plates 5 made of preferably 0.4-1.5 mm thick steel or

Made of aluminum sheet. They can be perforated to save weight and slightly wavy to improve the mechanical stability, which is also very good. At the front and rear edge, each corona electrode 3 is provided with a zone of curvature 6, in the area of which

Surface is strongly convexly curved. It is preferably produced by flanging the sheet and has the shape of a cylinder sector. Your radius of curvature is z. B. between 2 and 5 mm, preferably it is not larger than 4 mm. The curvature zones 6 each extend over the entire height of the filter lane 2, so that each

Flow trajectory inevitably goes through the area between the same and the separating electrode 1. The curvature zones 6 form the parts which protrude furthest to the side and have an approximately uniform curvature over their length.

The corona electrodes 3 are preferably between 10 and 40 cm long and follow one another at intervals of 20 to 50 cm. The plate-shaped design of the corona electrodes 3 forms an electric field in the filter alley 2, which is extremely homogeneous, particularly in the vicinity of the deposition electrode 1. This can be seen very well from FIG. 2a, where isolines are drawn in at a distance of 2 kV of that electrical potential, which forms while the DC voltage of 60 kV is present. The field strength in the area adjoining the deposition electrode 1 is approximately 2.4 kV / cm. No corona discharges occur at the curvature zones 6 when the DC voltage is present. However, if a voltage pulse of 26 kV is superimposed on it, 6 corona discharges form exclusively at the curvature zones, which generate the charge carriers required for the transport and separation of the dust or droplet-shaped contamination. 2b shows this case. Isolines of the electrical potential at a distance of 2 kV are also shown. Here, too, the field at the separating electrode 1 is very homogeneous.

The production of charge carriers can largely be influenced by several parameters independent of the generation of the electric field. In particular, the density of the curvature zones 6 in the flow direction of the gas is decisive for this. It can be set as desired by the distance between successive corona electrodes 3 and the length thereof in the flow direction. The strength of the corona discharges and the lower limit voltage for their occurrence can also be set by appropriately selecting the radius of curvature in the curvature zones 6 - in the present case the radius of the cylindrical flanges. In addition to the structural design of the filter arrangement and in particular the corona electrodes 3, the supply, in particular the adjustment of the length, height and repetition frequency of the voltage pulses, also offers the possibility of influencing the production of charge carriers. The structure and supply of the filter arrangement must be so are coordinated so that the desired functionality - with corona formation only during the voltage impulses and favorable charge carrier density - is achieved. The arrangement of the corona electrodes 3 according to FIG. 1 is almost ideal in terms of the homogeneity of the electric field.

3, on the other hand, corona electrodes 3 of the same design are inclined with respect to the flow direction, i. H. fixed about a central axis rotated parallel to the edges of the plate 5, alternately in the opposite direction. This reduces the effective electrical aisle width. The inclination of the corona electrodes 3 is therefore particularly suitable for the entrance area or for use in the area of waste heat boilers, where due to space charge

Corona suppression requires higher field strengths to trigger corona discharges. In addition, the robustness against malfunctions and assembly tolerances is higher.

The design of the filter arrangement according to FIG. 4 has similar properties. She is with

Corona electrodes 3 according to a second embodiment, each having a rectangular central plate 5a, which is aligned parallel to the deposition electrodes 1 and front and rear at an obtuse angle on opposite sides of shorter shorter plates 5b, which are also rectangular. At their free edges, the edge plates 5b have curvature zones 6 designed as flanges. 5 has corona electrodes 3 according to a third embodiment, in which two edge plates 5b connect symmetrically to the front and rear of the middle plate 5a, which project in a V-shape on opposite sides at an obtuse angle from the middle plate 5a . At their free edges, all edge plates 5b have curvature zones 6 designed as flanges. Due to the higher number of curvature zones, this design tends to result in a higher production of load carriers.

Claims

claims

1. Corona electrode (3) for an electrostatic filter arrangement for separating contaminants from a gas stream, characterized in that it comprises at least one essentially flat plate-shaped section and has at least one narrow curvature zone (6) extending over its entire height, in which its Surface is convexly curved, the at least one zone of curvature (6) having an approximately uniform curvature over its length and forming the part that protrudes the most from the side.

2. Corona electrode (3) according to claim 1, characterized in that the radius of curvature of the surface in the region of the curvature zone (6) is between 2 mm and 5 mm.

3. corona electrode (3) according to claim 1 or 2, characterized in that the curvature zone (6) has the shape of a cylinder sector.

4. corona electrode (3) according to one of claims 1 to 3, characterized in that the curvature zone (6) is arranged in each case on an edge of a plate-shaped section.

5. corona electrode (3) according to claim 4, characterized in that the curvature zone (6) is produced by a flange at the edge of the plate-shaped section.

6. Corona electrode (3) according to one of claims 1 to 5, characterized in that the at least one plate-shaped section consists of 0.4-1.5 mm thick steel or aluminum sheet.

7. Corona electrode according to one of claims 1 to 6, characterized in that it is designed as a rectangular plate (5).

8. corona electrode (3) according to any one of claims 1 to 6, characterized in that it comprises a rectangular central plate (5a), at the front and rear edge of which at least one rectangular edge plate (5b) protruding at an obtuse angle connects.

9. corona electrode (3) according to claim 8, characterized in that at the front and rear edge of the central plate (5a) each connect two rectangular edge plates (5b) projecting at opposite angles at an obtuse angle.

10. corona electrode (3) according to any one of claims 1 to 9, characterized in that its length is between 10 cm and 40 cm.

11. Electrostatic filter arrangement for separating contaminants from a gas stream, with at least two essentially flat separation electrodes (1), which form a filter lane (2) between them, in which several corona electrodes (3) according to one of the Claims 1 to 10 are successively arranged approximately centrally in the flow direction.

12. Electrostatic filter arrangement according to claim 11, characterized in that the distance between successive corona electrodes (3) is between 20 cm and 50 cm.

13. Electrostatic Fil eranordnung according to claim 11 or 12, characterized in that the corona electrodes (3) are inclined relative to the flow direction.

14. Electrostatic filter arrangement according to claim 13, characterized in that the inclinations of successive corona electrodes (3) are in opposite directions.

15. Method of operating an electrostatic

Filter arrangement according to one of claims 11 to 14, characterized in that an essentially constant negative direct voltage is placed between the corona electrodes (3) and the separating electrodes (1), the former forming the negative pole, which direct voltage is superimposed by voltage pulses of the same polarity , the DC voltage being dimensioned such that it does not cause corona formation, while the voltage pulses in each case lead to corona formation exclusively in the curvature zones (6).

16. The method according to claim 15, characterized in that the DC voltage is dimensioned such that between the voltage pulses, the field strength in the areas of the filter passage (2) adjoining the separating electrodes (1) is at least 2 kV / cm.

17. The method according to claim 15 or 16, characterized in that the voltage pulses follow one another at a frequency of 10 to 20 Hz.

18. The method according to any one of claims 15 to 17, characterized in that the voltage pulses have a length of 10 to 100 μs.

CHANGED REQUIREMENTS

[Received at the International Office on March 9, 1998 (March 9, 1998); original claim 1 amended; all other claims unchanged (1 page)]

1. corona electrode (3) for an electrostatic filter arrangement for separating contaminants from a gas stream, characterized in that it comprises at least one essentially flat plate-shaped section (5) which is aligned parallel or obliquely to the separating electrode (1) and at least one Narrow curvature zone (6) extending over its entire height, in which its surface is convexly curved, the at least one curvature zone (6) having an approximately uniform curvature over its length and forming the most protruding part laterally.

2. Corona electrode (3) according to claim 1, characterized in that the radius of curvature of the surface in the region of the curvature zone (6) is between 2 mm and 5 mm.

3. corona electrode (3) according to claim 1 or 2, characterized in that the curvature zone (6) has the shape of a cylinder sector.

4. corona electrode (3) according to one of claims 1 to 3, characterized in that the curvature zone (6) is arranged in each case on an edge of a plate-shaped section.

5. corona electrode (3) according to claim 4, characterized in that the curvature zone (6) is produced by a flange at the edge of the plate-shaped section.

CHANGED SHEET (ARTICLE