SE506423C2 - Method for controlling the length of the stroke intervals and other stroke parameters at an electrostatic dust separator - Google Patents

Abstract

A method for controlling an electrostatic precipitator unit, comprising discharge electrodes and collecting electrodes, between which a high voltage is maintained by a direct current supplied to the electrodes. Dust deposited on the collecting electrodes is removed by mechanical rapping of the collecting electrodes by mechanical impulses being supplied to the electrodes individually or in groups. The collecting electrodes of the precipitator unit are cleaned during recurrent, relatively short, rapping periods separated by rapping intervals, of considerably longer duration. A strategy of controlling the electrical parameters is selected and this strategy is maintained during the optimisation. The length of the interval between the rapping periods and possibly also other rapping parameters are varied. The current and voltage during the interval between the rapping periods are measured. The average ofthe current, voltage, or a quantity derived from the currrent and/or voltage, during the interval between the rapping periods, is calculated. This calculated average is used for controlling the length of the rapping intervals and/or other rapping parameters.

Description

The dust cake at the precipitation electrode by its growth gradually deteriorates the function of the filter, beating is desirable before the dust cake becomes too thick. On the other hand, during each stroke a considerable amount of dust is released which is returned to the flue gas, with a momentarily reduced degree of separation as a result.

In addition, too high a beating frequency leads to the formation of a hardening coating on the precipitating electrode which can no longer be removed by beating. The selected beating frequency will be a compromise that, for example, will maximize the average degree of separation. Other stroking parameters that can be varied are the number of strokes during each stroke and their strength. The electrical voltage between the emission electrode and the precipitation electrode can also be lowered, disconnected or even reversed during the beating to facilitate the release of the dust during the beating. Reversal is described, for example, in SE 455 048.

An electrostatic precipitator consists of a number of separator units that are connected in series. Since the amount of dust separated per unit time decreases sharply with the number of separator units that the flue gas has passed, the beating must be regulated separately for each separator unit. However, in order to be able to separate released dust in a later separator unit when striking in a separator unit, the striking must be coordinated so that it is not carried out simultaneously in several separator units. Also the beating sequence in a separator unit. which contains a plurality of separation electrodes to be beaten, is carefully selected so that all plates are beaten once during a so-called beating cycle, where the beating sequence between the plates has been chosen with the aim of minimizing the return of dust to the flue gas.

The growing number of control parameters of an electrostatic precipitator has increased the complexity of the control systems. A problem with this is that the very adjustment of the beating parameters of the soal42, such as the beating frequency, increases the disturbance in the function of the separator.

If the adjustment of the beating frequency, for example, is done manually with the aid of the reading on an opacity meter (smoked tf heat meter), the adjustment takes so long that an unfavorable value of the beating frequency during the adjustment can lead to increased emissions during the setting time. In addition, there is a risk that operational variations will negatively affect the adjustment if significant changes in the dust concentration occur, “the dust composition or gas temperature occurs during the time required for the adjustment. This already applies to the adjustment of the separator's electrical parameters and is an even more difficult problem when adjusting V, for example the beating frequency because the beating frequency varies between minutes for the first separator unit to several hours or even days for the last.

US 4,432,062 describes an automatic optimization of strokes; frequency with respect to the mean value of the residual dust content in the flue gas after the filter. The disadvantages of this: method is dependent on the measurement of the remaining dust content in the flue gas and that the beating frequency varies over several orders of magnitude between the separator units. When selecting the beat frequencies of the separator units as independent parameters, this leads to a simultaneous optimization of many: parameters, something that easily leads to sub-optimization or lack of convergence of the optimization algorithm. If pre-determined functional relationships are chosen between the beating frequencies, for example constant relative conditions, on the other hand the number of degrees of freedom is limited too much, with the risk of sub-optimization. Corresponding conditions apply to other beating parameters, for example the voltage during beating. 10 15 20 25 30 35 506 423 It has been shown that the methods tested so far for controlling the beating parameters do not always lead to the optimal parameter combination and, above all, are far too slow.

DESCRIPTION OF THE INVENTION The invention relates to a method for an electrostatic precipitator unit, comprising emission electrodes and precipitation electrodes, between which a high voltage is maintained by a constant or pulsating direct current supplied to them, so that under the influence of the electric field between the particles charged by the current between these are carried towards precipitation electrodes and deposited thereon, whereby dust deposited on the precipitation electrodes is removed by mechanical beating of the precipitating electrodes, controlling the length of the beating intervals and other beating parameters.

You select a control strategy for the electrical parameters and maintain this strategy during the optimization. You vary the interval between strokes and can also vary other strokes parameters such as number of strokes, stroke strength and current or voltage between the electrodes during the stroke period. Current and voltage are measured during the interval between beatings, the mean value of the current, the voltage or any of the current and / or the voltage derived magnitude are measured during the interval between beatings, and this calculated mean value is used to control beating intervals and other beating parameters.

The object of the invention is to maximize an average degree of dust separation by means of suitable control strategies approximately during the beating intervals in order to minimize dust emissions in a plant which comprises the electrostatic dust collectors. 10 15 20 25 30 35 506) 423 When a dust layer is built up on the precipitating electrodes, it causes a voltage drop across the dust layer which is substantially proportional to the thickness of the dust layer. The thicker the layer, the greater the part of the voltage between the emission electrodes and the precipitation electrodes is over the dust layer. This leads to reduced current if the voltage between the electrodes is maintained. To maintain the same current, the voltage must be increased. With increasing thickness of the dust layer, the degree of separation decreases. Since the derivative of the voltage in this case is substantially proportional to the amount of dust separated per unit time, this manifests itself in the fact that the derivatives of the voltage decrease with time, as shown in Fig. 3, see the description below. The decreasing degree of separation during the interval between the beating periods could apparently be met by making the beating intervals as short as possible. It turns out, however, that when cleaning: a residual layer is always left after the beating and that this residual substance layer has a thickness that increases with decreasing length of the beating interval. The consequence is that at short beating intervals you start higher up on the voltage curve immediately after beating and can not credit the part of the voltage curve that has the largest derivative when choosing longer beating intervals.

If you therefore compare short and long voltage intervals, fi you realize that with short intervals you get a relatively lower degree of separation in the beginning which does not decrease as much _ during the interval, while with long intervals you get a higher degree of separation in the beginning but a stronger decrease to a relatively added value at the end.

This means that one can find an optimal beating interval with an average highest degree of separation, with the exception of beating losses, by choosing a suitable control strategy. In addition, there will of course be an increase in the losses during beating by having short beating intervals, but this is outside the scope of the present invention.

How to find the optimal beating interval depends to a large extent on the current electrical control of the electrostatic precipitator unit. If the current is kept constant, it may be appropriate to seek the minimum average voltage or the maximum average increase (voltage derivative). If the voltage is kept constant, it may be appropriate to seek the maximum average current. If the current must be limited due to the fact that so-called re-radiation from the dust layer causes the voltage to drop when the current increases above a certain value, it may be appropriate to seek to maximize the average power. If the separator unit is controlled so that you seek to work close to the limit of electrical surge, this essentially corresponds to operation with constant current. It is the field strength of the gas, rather than the voltage between the electrodes, that determines the flashover level, and the control principle can be selected approximately as if the current is kept constant.

An additional control strategy maximizes a quantity other than the average power derived from the current and / or voltage during the beating interval.

An additional control strategy is that during the interval between the beats, current and / or voltage are controlled, in a manner known per se, so that the electrostatic dust collector unit works close to its override limit under current conditions.

Within the scope of the inventive concept, one can also choose to carry out a simultaneous optimization of at least two beating parameters such as the length of the beating interval, number of beats, beating force and current or voltage between the electrodes during the beating period. 10 15 20 25 30 35 5o§ 42s It is possible to apply several consecutive beats even during a beating period of the usual precipitation electrode and thereby, fl between the consecutive beats, gradually lower the voltage between the electrodes or the current to the electrodes. L DRAWING LIST Fig. 1 schematically shows a dust separator for carrying out the current procedure. * A Pig. Fig. 2 schematically shows the current as a function of time during some beating intervals while maintaining the voltage for two different lengths of the beating intervals, Figs. 2a and 2b. "Fig. 3 schematically shows the voltage as a function of time during some beating intervals at constant holding of the current for two different lengths of the beating intervals, A Figs. 3a and ab. Ii DESCRIPTION OF EMBODIMENTS, of the current process. outlet duct 42 and comprises three dust separator units 1, 2, 3, each with a dust pocket 11, 12, 13. Separator 1 Fig. 1 schematically shows a dust separator for the feed-through units fed with direct current from three rectifiers 21, p and 23. The rectifiers 21- 23 is controlled and monitored by a control unit 30.

This control unit 30 also communicates with devices Si, 52 and 53 for beating the precipitation electrodes in the dust separators 1, 2 and 3.

Pig. 2 shows schematically how the current I through a separator unit varies with the time during a beating interval 2 if the voltage U between the electrodes is kept constant. By? the increase in the thickness of the dust layer decreases the current by '10 15 20 25 30 35 506 423 time. The maximum current immediately after a beating period S is higher after a long beating interval Zb). (ïamax, Fig. 2a) than after a short (Ibmax, Pig.

Pig. 3 shows schematically how the voltage U across a separator unit varies with the time during a beating interval T if the current I through the separator unit is poured constantly. By increasing the thickness of the fabric layer, the tension increases with time.

The minimum voltage immediately after a beating period S is lower after a long beating interval (Ubmin, 3b).

(Uamin, Fig. Ba) than after a short Pig.

With the help of Pig. 3, embodiments of the method can now be clarified. Short beating intervals lead to a thicker residue layer on the precipitating electrode which results in a higher voltage Ubmin immediately after a beating period S (Fig. 3b). A longer beating interval means a thinner residual dust layer and thus a lower voltage Uamin (Fig. 3a).

On the other hand, the curvature downstream of the stress curve, which relates to gradually deteriorating dust separation, becomes larger towards the end of the beating interval. A control strategy now aims to determine an optimal length of the beating interval which, at constant current, minimizes the average value of the voltage during the beating interval. Another control strategy is instead to determine an optimal length of the beating interval that maximizes the voltage derivatives during the beating interval.

Both control strategies lead to a length of the beating intervals that leads to an approximately maximum average degree of dust separation during the beating interval.

In a similar way, starting from Pig. 2 a control strategy is selected which is based on determining the length of the beating interval which, at constant voltage, maximizes the average value of the current during the beating interval.

Claims (13)

10 I5 '20 25 30 35 sosg42s PATENTKRAV A method for using an electrostatic precipitator unit (1, 2, 3), comprising emission electrodes and precipitation electrodes, between which a high voltage is maintained by a constant or pulsating direct current supplied to them, so that under the influence of the electric field between the rods are those of the current between these charged particles I which are carried towards the precipitation electrodes and deposited thereon; dust deposited on the precipitating electrodes is removed by mechanical beating of the precipitating electrodes, by: one or more mechanical impulses are applied to the electrodes individually or in groups in a predetermined manner, so that all the precipitating electrodes Sectioning intervals of significantly greater length, control the length of the beating intervals and other beating parameters. characterized by selecting a control strategy for the electrical parameters and maintaining this strategy during optimization, varying the interval between strokes and can also vary other stroking parameters such as number of strokes - stroke strength and current or voltage between electrodes during the stroke period. and voltage during the interval between strokes. 1 “In calculating the average value of the current, voltage or any of the current and / or voltage hairy magnitude during the interval between the beating times, then V and that you use this calculated mean value to control beating interval and other beating parameters. V '10 15 20 25 30 35 506 425 10 2. A method according to claim 1, characterized in that the average value of the current is measured during the interval between the beatings and that the beating interval and other beating parameters are regulated so that a mean average value is reached as possible. 3. A method according to claim 1, characterized in that the average value of the voltage is measured during the interval between the beatings and that the beating interval and other beating parameters are regulated so that a mean value is reached as possible. 4. A method according to claim 1, characterized in that the average value of the product of current and voltage is measured during the interval between the beatings and that the beating interval and other beating parameters are regulated so as to reach as high an average value as possible. 5. A method according to claim 1, characterized in that the average value of the time derivative of the voltage is measured during the interval between the beatings and that the beating interval and other beating parameters are regulated so that as high an average value as possible is reached. Method according to one of Claims 1 to 5, characterized in that the beating interval is varied but the other beating parameters are kept constant. Method according to one of Claims 1 to 5, characterized in that the current supply to the electrodes or the voltage between the electrodes is varied during the beating period, but the beating interval is kept constant. 10 15 20 25 30 35 5Û6¿425 11 Method according to one of Claims 1 to 5, characterized in that the number of beats or the magnitude of the impulse applied in each beat is varied, but the beating interval and other beating parameters are kept constant. 9. A method according to any one of claims 1 to 5, characterized in that the voltage is kept constant during the interval between the beatings. Method according to one of Claims 1 to 5, characterized in that the current is kept constant during the interval between beatings. Oh Method according to one of Claims 1 to 5, characterized in that during the interval between the beating cill cases the current and / or voltage are controlled in a manner known per se, so that the electrostatic dust collector unit operates close to its overflow limit. under current conditions fi äenf A method according to any one of claims 1 to 5, characterized in that several consecutive beats are applied to each precipitating electrode during each beating period and thereby, between the consecutive beats, the voltage between the electrodes is gradually lowered. IN 13. A method according to any one of claims 1 to 5, characterized in that during each beating period several consecutive beats are applied to each precipitating electrode and thereby, between the consecutive beats, the current to the electrodes is gradually reduced.