SU919747A1 - Electric filter operation control method - Google Patents

Description

(54) METHOD OF OPERATING THE ELECTRIC FILTER

I

The invention relates to methods for controlling the operation of an electrostatic precipitator and can be used in heat and power engineering, metallurgy and other industries.

There is a known method of trapping high impedance dusts by using pulsed unipolar voltage to power the electrostatic precipitator 1.

The disadvantage of this method is that the cleaning efficiency cannot be increased by increasing the frequency of the pulses, since an excess charge accumulates on the dust layer, leading to a breakdown of the layer, i.e. to the appearance of the inverse of the crown.

Closest to the invention in its technical essence and the achieved result is a method for controlling the operation of an electrostatic precipitator, in which the dust-gas flow is affected by cyclically varying voltage of alternating polarity with an equal amount of electricity in the positive and negative parts of cycle 2.

The disadvantage of this method is that the oil does not provide high speed

the movement of particles to the precipitation electrode and the correspondingly high degree of gas purification in each part of the cycle due to the constant voltage in the positive and negative parts of the cycle. In addition, the supply voltage of the electrostatic precipitator changes its sign to the opposite when the charge reaches a critical value. However, by the time the voltage is changed, the dust layer does not have time to recharge and retains the previous value of the charge in sign. Since the polarity of the voltage changed, a force is applied to the deposited layer for a while, directed not to the plane of the precipitation electrode, but rather from it. As a result, the precipitated dust particles return to the dust gas flow, and the efficiency of the electrostatic precipitator decreases.

The purpose of the invention is to increase the efficiency of dust collection.

20

Claims (2)

This goal is achieved by effecting the dust and gas flow by pulsating voltage in the positive and negative parts of the cycle. 39 In FIG. Figure 1 shows the shape of the cyclic voltage and the curve of the change in the charge density; in fig. 2 is a diagram of a device for feeding electrostatic precipitators; trapping high resistance dust that implements this method. FIG. 1 and 2 are marked; Ua is the amplitude over the voltage; DO is the initial voltage; T, T. duration of the positive and negative parts of the cycle; tn - Pause duration; ty pulse duration; g is the charge density ;. T - the duration of the cycle. The method is carried out as follows. The control unit 1 controls the switch 2 with the control winding 3 and the wires 4 connected to them. The control signals over the wires 5 and 6 are transmitted respectively to the pulse drivers 7 and 8, which are provided with the generators 9 and 10. The switch 2 has wires 11 and 12 is electrically connected to generators 9 and 10, and is also connected to a corona electrode. 13 of the electrostatic precipitator 14. In the upper position of the contact of the switch 2, the voltage is supplied from the generator 9 through the wire 11 to the corona electrode 13 of the electrostatic precipitator 14. The generators 9 and 10 are thyristor switches, each of which is connected to a high voltage transformer. One of the (generators) provides the voltage on the electrostatic precipitator in the positive part of the cycle, and the second in the negative part. A phase shifter is used as pulse shaper 7 and 8, operating in its own unit with a predetermined mode. From the pulse formers 7 and 8, the thyristor keys of the generators 9 and 10 are received by the triggering pulses that are out of phase with respect to the key supplying to the yarn in such a way that the output of the key from a series of high voltage waves is generated by the necessary shape of the pulses velocity of the first pulse. The pulse shapers 7 and 8 are controlled by the control unit 1. The device provides a voltage on the load (electrostatic precipitator 14), the shape of which is shown in fig. 1. In the period from O to tj, the electric capacitance of the electrostatic precipitator 14 is charged, the voltage rises along the OK curve, there is no electric current between the electrodes, since the voltage between the electrodes is lower than the initial voltage UQ. Further, the voltage grows, but direct KL begins, the corona discharge begins, the particle IC1 1 dust acquires a charge and is deposited, creating a charge on the noBcpxHocTHbni elec trode. In FIG. 1 also shows the curve of the change in the charge density. On the true curve g, the value of the charge absorption would increase during the pulse tu and would hardly change during the pause t. This simplification is a reference law, since in this case the process of accumulation of charge in the layer is not distorted as a whole. From FIG. 1 it follows that the charge density curve does not begin with a zero (axis t), but from time IK, i.e. since the beginning of the corona discharge and reaches a critical value at the point N, which corresponds to a time t T. If the positive part of the cycle continued further, the charge density g would reach a critical value, the dust layer would test and the inverse corona would appear. The duration of a positive TC. and the negative T part of the cycle is determined by adjusting the dust collection system. In order to increase the reliability of the device and, taking into account possible fluctuations of the process, take the duration of the parts, the cycle, equal to about 0.9 of the true duration of the corresponding part of the cycle. At the time t of the control unit 1 (Fig. 2), a pulse arrives at the control winding 3 of the switch 2, moving its contact to the lower position, and a control signal is applied to the pulse shaper 8, which turns it on. In this case, the generator 9 is turned off and the generator 10 is connected, the polarity of the supply voltage is changed on the corona-forming electrode 13, the negative part of the T. cycle acts. During the time period (Fig. 1) from Q to F, the dust layer is recharged, the electric force separating the charged particles is reduced, and less adhesion and cohesion forces. The precipitated dust is not disrupted back into the dust-gas stream, as a result of which the degree of purification increases. During the period when the charge density passes through point F, the vacuum cleaner self-obstructs. I In the following, the process in the negative part of the cycle is similar to the process in the positive part. Due to the pulsating nature of the voltage, the duration of both a positive T. and a negative part of T. increases by several orders, therefore, the voltage switching frequency decreases to such an extent, and hence the effect of the switching process on the decrease in the efficiency of the electrostatic filter decreases. The advantage of a pulsating voltage over a constant value is based on the fact that the electrical strength of the electrostatic gap of an electrostatic precipitator is higher when the voltage of the electrostatic electrostatic power supply is pulsed compared to a constant voltage of a constant value. The increase in ripi) voltage and (increase in breakdown voltage) is explained by the resorption of the volume charge existing in the interelectrode gap during the pause between pulses. At a constant voltage of the same magnitude, the accumulated volume charge redistributes the electric field, thus reducing the breakdown voltage. Since the charge of a particle is proportional to the intensity of the electric field, an increase in the voltage during a pulsed power leads to an increase in the charge of the particles, which in turn provides a high rate of movement of particles to the precipitation electrode, i.e. high degree of gas purification in each part of the cycle. The first pulse in each part of the cycle cannot have a very steep leading edge, since the deposited layer has a certain constant reloading time. Therefore, in order to prevent the deposition of a deposited layer of dust from the precipitating electrode, when the polarity changes, the voltage across the electrodes should increase smoothly, i.e. the top of the first pulse must be skewed. In this case, in the process of increasing the voltage, the charge of the layer is neutralized by the flow of ions from the corona-forming electrode, which has a charge opposite to the sign of the charge of the layer of dust. Reducing the charge of the dust layer increases the voltage between the electrodes, while the electrical forces acting on the layer and directed at this moment from the precipitation electrode should be less than the adhesion and cohesion forces of the dust in order to prevent the dust layer from falling off the precipitating electrode. In the future, the charge of the dust layer decreases to zero, and then its charge is charged with oppositely charged electricity. In addition, the implementation of parts of the cycle by pulsating, rather than constant voltage, allows to significantly increase the duration of parts of the cycle. This is due to the fact that with a pulsating voltage, the average current density decreases, as a result of which the rate of accumulation of charge in the layer decreases and the time to reach the maximum charge at which the dust layer penetrates increases. An increase in the duration of parts of the cycle leads to a decrease in the frequency of switching the voltage polarity by several orders of magnitude, as a result of which the loss in dust collection efficiency due to voltage switching is reduced. The loss of efficiency when the polarity of the voltage on the corona electrode is changed is due to the fact that the particles cannot instantly change sign, and this recharging process takes a certain time during which the particles do not move in the direction of the precipitation electrode. With this form of voltage supply to the electrostatic precipitator, the process of dust electrodeposition is normalized, since the inverse corona is eliminated. The reverse corona cannot arise for the reason that the durations of both the positive and negative parts of the cycle are taken somewhat less than the time it takes for the critical charge to accumulate in the layer when it breaks through and the reverse corona sets in. Claims The method of controlling the operation of an electrostatic precipitator is by acting on a dust-gas flow by a cyclic varying voltage of variable polarity, characterized in that, in order to increase the efficiency of dust collection, the impact on the dust-gas flow is carried out by pulsating voltage in the positive and negative parts of the cycle. Information sources,. taken into account during the examination 1. Electricity, M., 1978, N 4, p. 70-71. 2. USSR author's certificate number 548315, cl. B 03 C 3/38, 1974. h Un; (J M f-t- II +1 X ff O. 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