RU2720861C1 - Frame of shaking mechanism of hammer type of corona electrodes of wet electrostatic precipitator - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to electrical cleaning of gases. In the frame of the shaking mechanism, corona-forming electrodes with weights are arranged axisymmetrically in a precipitation electrode in the form of a round or polygonal tube. Corona-forming electrodes are vertically fixed in the suspension frame. Frame of the shaking mechanism is fixed on the suspension frame, located under the electrodes and is equipped with an anvil for interaction with the hammer type mechanism. Frame for each row for fixing electrodes against transverse displacement is made of crosswise beams metal cross-section interconnected by lengthwise beams. Each transverse beam is made of two angular profiles facing each other at a distance providing the arrangement of a row of corona-forming electrodes with a gap of not more than 1.5 mm. To fix the corona-forming electrodes from longitudinal displacement, each electrode is equipped with a metal plate bent to fix transverse beams on the lower surface of the angular profile with a cutout for passage of the electrode with a gap of not more than 1.5 mm. In order to centering the corona-forming electrode with respect to the precipitation electrode on the plate, elliptical holes are made on both sides.

EFFECT: simplified design, increased efficiency of cleaning corona-forming electrodes by mechanical shaking.

5 cl, 4 dwg

Description

The invention relates to a device for the electrical cleaning of gases from fine dust and can be used in industries such as metallurgical, chemical, oil refining and others.

The known mechanism of shaking the hammer type of the corona electrodes of the electrostatic precipitator from patent 2152261, the corona electrodes in the wet electrostatic precipitator are located vertically and are fixed only from above, and below they are not fixed and are located in the precipitation electrodes. As dust accumulates on the corona electrodes, they are regenerated by lifting and dropping the hammers on the anvil. When impacted, the corona electrodes undergo vibration and deviate from a symmetrical arrangement, which leads to electrical breakdowns and short circuits. To exclude vibrations and build-up of suspended corona electrodes, as well as their symmetrical arrangement with respect to precipitation electrodes, the lower guide frame is fixed by insulators and due to the hinged connection of the suspension and vibration damper.

The known design is difficult to manufacture, not effective enough due to the fact that the lower frame prevents the corona electrodes from moving only in the longitudinal direction, therefore, breakdowns of electricity and short circuits are possible.

The basis of the invention is the task of improving the gas purification device by using a mechanical cleaning device of electrodes from dust adhering to them. Such a device is a hammer-type shaking mechanism of the corona electrodes of a wet electrostatic precipitator, which does not require stopping the electrostatic precipitator.

The technical result achieved is to simplify the design, increase the productivity and efficiency of cleaning the corona electrodes by mechanical shaking from the dust accumulated on them, which prevents the creation of a dense electric field by transmitting shock and vibration impulses from hammers to corona electrodes, activating their vibration and, as a result, removing from the surface of the corona electrodes deposited during the cleaning of dust particles.

This result is achieved by the fact that the frame of the hammer-type shaking mechanism of the corona electrodes of the wet electrostatic precipitator, in which the corona electrodes with weights located axisymmetrically in the precipitation electrode in the form of a round or polyhedral tube, and the corona electrodes are arranged vertically fixed in the suspension frame. The frame of the shaking mechanism is mounted on the suspension frame, located under the electrodes and equipped with an anvil for interaction with the hammer-type mechanism. The frame for each row for fixing the electrodes from lateral displacement is made of interconnected longitudinal beams of metal angular profile of the transverse beams. Each transverse beam is made of two angled profiles facing each other by surfaces at a distance that ensures the location of a number of corona electrodes with a gap of no more than 1.5 mm. To fix the corona electrodes from the longitudinal displacement of the electrode, each electrode is equipped with a metal plate curved to fix the transverse beams on the lower surface of the angular profile, with a cutout for the electrode to pass with a gap of no more than 1.5 mm, and to center the corona electrode relative to the precipitation on the plate made elliptical holes on both sides.

-образным, а также тем, что используют коронирующий электрод игольчатого типа или спирального типа, или в виде нити.This result is also achieved by the fact that carbon or heat-resistant steel or titanium alloy is used as metal, that a frame-type metal structure is welded to the bottom from the frame, welded from several seamless or electric-welded pipes, which have to hit the hammers through the anvil and that the cut in a metal plate is made U-shaped or

-shaped, as well as the fact that a corona electrode of needle type or spiral type or in the form of a thread is used.

In FIG. 1 schematically shows an electrostatic precipitator according to the invention,

in FIG. 2 shows the transverse beam of the frame with the location of the corona electrode,

in FIG. 3 - the same, bottom view,

in FIG. 4 - node A in figure 1 of the hammer type mechanism.

The frame 1 of the hammer-type shaking mechanism of the corona electrodes 2 of the electrostatic precipitator, in which the corona electrodes 2 with weights 3 located axisymmetrically in the precipitation electrode are vertically fixed in the suspension frame 4. The frame 1 of the shaking mechanism is mounted on the frame 4 of the suspension, located under the electrodes and equipped with an anvil 5 for interaction with the mechanism of the hammer type. In this case, the frame 1 for each row of corona electrodes 2 for fixing the electrodes from lateral displacement is made of transverse beams 6 connected by longitudinal beams of metal angular profile. Each transverse beam 6 is made of two angled profiles facing each other at a distance that ensures the location of the row corona electrodes 2 with a gap of not more than 1.5 mm To fix the corona electrodes 2 from longitudinal displacement, each electrode is equipped with a metal plate 7, curved for fixing on the lower surface of the angular profile of the transverse beams 6, with a cutout for passing the corona electrode 2 with a gap of not more than 1.5 mm, and for centering the corona electrode 2 with respect to precipitation, elliptical holes are made on the plate 7 on both sides.

Frame 1 is developed for a specific type of wet electrostatic precipitator, which can be either round or square. The longitudinal beam is made of channels to it by means of a bolted connection, the transverse beams 6 are made of angular metal profile. For the most uniform transmission of the shock pulse to the bottom of the frame 1, a metal structure is rigidly fixed, welded from several seamless or electric-welded pipes 8 d = 40-80 mm, which are hit by hammers 9 through anvils 5 with a diameter of d = 90-120 mm. All structural elements are made of carbon or heat-resistant steel, or titanium alloy.

At the installation site of the corona electrode 2, by means of a bolted connection, a metal plate 7 is attached to the transverse beams 6 of the frame 1 of the shaking mechanism. The main task of the plates is to limit the longitudinal movement of the corona electrodes 2, from the transverse movement they are limited by the transverse beams 6 themselves, since the electrode passes between them. This eliminates the deflection of the electrodes in longitudinal and transverse deflection when shaking during operation and, as a result, observing the interelectrode distance between the corona and precipitation electrodes, which ensures the creation of a more dense electric field.

In each plate 7, two elliptical holes are made, having a length of not more than 15 mm and a width of not more than 7 mm. Using elliptical holes, you can fine tune the location of the corona electrode. This allows you to accurately center the corona electrodes in relation to the precipitation and to avoid breakdowns of electricity and short circuit.

The transverse beams 6 of the frame 1 and the plate 7 provide reliable fixation of the corona electrodes 2 and their alignment with respect to the precipitation electrodes.

Using elliptical holes, the corona electrodes 2 adhere to the transverse beams 6 of the frame 1, sufficient to transmit the shock impulse from the percussion hammers 9 through the anvil 5 and the frame 1 of the shaking mechanism, followed by vibration and removal of accumulated dust.

The device operates as follows.

During the operation of the shaking mechanism, the shaft rotates, on which the shock hammers are fixed 9. The weight of the hammers 9 and the frequency of the shocks are selected and adjusted directly at the place of use depending on the operating conditions of the electrostatic precipitator.

The shock impulse of the hammers 9 is transmitted to the anvil 5.

Due to the rigid connection of all elements of the shaking system, the shock pulse wave-like propagates through the frame 1 of the shaking mechanism and is transmitted to the corona electrodes 2.

The corona electrodes 2, under the influence of the propagating shock wave, begin to vibrate the dust settled on them during the cleaning process is easily separated. The filter shutdown time for flushing is reduced, costs and production downtime are reduced.

The invention allows to improve the degree of gas purification by an electrostatic precipitator at a lower voltage, due to the cleaning of the electrode from dust obtained by using the frame of the shaking mechanism, which allows you to create a dense electric field, which increases the degree of purification and efficiency of the electrostatic precipitator, as well as reduce production costs and downtime.

Claims (5)

1. The frame of the hammer-type shaking mechanism of the corona electrodes of the wet electrostatic precipitator, in which the corona electrodes with weights are located axisymmetrically in the precipitation electrode in the form of a round or polyhedral tube, the corona electrodes are vertically mounted vertically in the suspension frame, the frame of the shaking mechanism is fixed on the suspension frame, located under the electrodes and equipped with an anvil for interaction with a hammer-type mechanism, the frame for each row for fixing the electrodes from lateral displacement is made of longitudinal beams connected to each other by longitudinal beams of the metal angular profile, while each transverse beam is made of two angled profiles facing each other at a distance that ensures the location of the row of corona electrodes with a gap of not more than 1.5 mm, and for fixing the corona electrodes from the longitudinal displacement of the electrode, each electrode is equipped with a metal plate bent to fix leaking on the lower surface of the angular profile of the transverse beams with a cutout for the passage of the electrode with a gap of not more than 1.5 mm, and for centering the corona electrode relative to the precipitation on the plate there are elliptical holes on both sides. 2. The frame according to claim 1, characterized in that the metal used is carbon or heat-resistant steel, or a titanium alloy. 3. The frame according to claim 1 or 2, characterized in that a metal frame-type structure is welded to the bottom from the bottom, which is welded from several seamless or electric-welded pipes, which account for the impact of hammers through the anvil. 4. The frame according to claim 1, characterized in that the cutout in the metal plate is made U-shaped or

-shaped. 5. The frame according to claims 1 to 4, characterized in that they use a needle-type corona electrode or a spiral type, or in the form of a thread.

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