RU117832U1 - ELECTRIC CATCH OF GALVANIC AEROSOLS - Google Patents

Abstract

1. An electric trap for galvanic aerosols, in the body of which there is a catching part, consisting of electrodes of alternating polarity, characterized in that the electrodes consist of vertical plates with ribs protruding perpendicularly on them and are located parallel to each other so that the edge of the electrode is of the same polarity located between the edges of the electrode of a different polarity. ! 2. An electric trap according to claim 1, characterized in that the bottom of the housing contains sloped grooves for condensate drainage. ! 3. An electric trap according to claim 1, characterized in that the electrodes are attached to the body by means of pins fixed on one side of the electrodes, and on the other side through holes for fastening on insulators. ! 4. An electric trap according to claim 3, characterized in that the insulators are provided on the outside with side covers hermetically connected to the body, which in the upper part contain holes with tubes. ! 5. Electric trap according to claim 3, characterized in that the insulators are made in the form of plates. ! 6. An electric trap according to claim 5, characterized in that the insulators are fixed on the front and rear walls of the housing by means of racks.

Description

The utility model relates to devices for purifying air from dispersed particles, in particular aerosols emitted from galvanic baths.

A device for collecting liquid aerosols containing electrodes connected to different poles of a high-voltage current source is installed in the housing, one of which is made in the form of interconnected metal plates, the other electrode is made in the form of a tubular heat exchanger of curvilinear periodic shape (patent for the invention of the Russian Federation No. 2050979 IPC V03C 3/16, 1995).

However, in the case of an automatic line, the presence of such a heat exchanger in the device reduces its reliability, complicates the design and its operation.

A device for collecting liquid aerosols is known, in which the electro-collecting part consists of two electrodes. The upper electrode in the form of a continuous horizontal metal plate is mounted with an insulator on the trap cover. The lower electrode in the form of a grid, alternating with field concentrators oriented towards the upper electrode perpendicular to it, plays the role of a collecting electrode and contacts the body of the bath. The air channel between the electrodes is in communication with the duct of the ventilation system. The inclined panel, consisting of alternating grids and gutters, acts as a droplet eliminator and defoamer and provides shock-free drainage of condensate into the bath (patent for utility model of the Russian Federation No. 91896, IPC V03C 3/16, 2009)

The disadvantage of this device is the complexity of preventive cleaning of the trap during operation.

Another disadvantage is the location of the lid with an electrode covering the entire surface of the bath, which is not permissible in the case of an automatic line.

The closest to implementation is a device for trapping liquid aerosols, in which the same type of electrodes of a Y-shape, alternating polarity are located so that the end (bottom) of the shelf of one electrode is opposite the length of the shelf of the other electrode and is perpendicular to it (patent for utility model of the Russian Federation No. 80129, IPC В03С 3/16, 2007).

The disadvantage of this device is the short path of the particles in the area of their capture, that is, the short time of the electric field, and, therefore, the lack of efficiency of capture of contaminants.

The technical result of the utility model is to increase the efficiency of pollution capture by increasing the path of aerosols in the interelectrode space.

The technical result is achieved by the fact that in the electrocatcher of galvanic aerosols, in the housing of which there is a collecting part, consisting of electrodes of alternating polarity, the difference is that they consist of vertical plates with ribs perpendicular to them and arranged parallel to each other so so that the edge of the electrode of one polarity is located between the edges of the electrode of another polarity.

With this arrangement of electrodes, an inhomogeneous electric field is formed between them. The presence of ribs on the plates contributes to the formation of a tortuous duct, which increases the path length of the aerosols, and thereby the efficiency of their capture.

In the proposed device, the electrodes can be attached to the housing using pins mounted on one side of the electrodes, and on the other hand through holes for mounting on insulators, made for example in the form of plates mounted in turn on the front and rear walls of the housing using for example, racks. The insulators must be in a dry state, as otherwise an interelectrode breakdown will occur. To keep the insulators dry, they can be protected from the outside by side covers that are hermetically connected to the housing, and to prevent the ingress of electrolyte droplets from the galvanic bath through the inlet window into the space with insulators, they can contain openings with tubes (bypass tubes) in the upper part of these covers for supplying countercurrent air from an area inaccessible to drip entrainment.

Ventilation in the device can be carried out through an opening in the top cover of the housing - an exhaust ventilation opening using, for example, a fan.

An additional technical result of the utility model is the availability of means for collecting condensate and returning it to the bath. This increases the economic effect by reusing the electrolyte.

An additional technical result is achieved by the fact that the bottom of the housing contains grooves with a slope for condensate drain.

Figure 1 presents a General view of the device, and figure 2 is a fragment And the mounting of the electrodes, where 1 is the body; 2 - cover; 3 - exhaust vent; 4 - side covers; 5 - bypass tubes; 6-input window; 7 - bottom; 8 - inclined grooves; 9 - electrodes; 10 - insulator; 11 - mounting studs; 12 - holes for mounting electrodes.

The device operates as follows.

Through the inlet window in the lower part of the casing, under the action of the ventilation stream, the air containing droplet aerosols from the electroplating bath enters the interelectrode space, where the droplets are captured by the electrodes partly under the influence of the inertial mechanism, and partly under the influence of the dipole mechanism (the movement of polarized droplets in an inhomogeneous electric field in the direction of the field of greater intensity, i.e. to the ribs, due to the fact that the electrodes consist of vertical plates with ribs perpendicular to them, and are arranged in parallel with respect to each other so that the edge of the electrode of one polarity is located between the edges of the electrode of another polarity). The trapped droplets on the electrodes coagulate, and the coarse droplets fall into the lower region at the bottom of the casing, with the inclined grooves extruded to drain the electrolyte into the bath. To prevent wetting of the insulators with electrolyte, the latter are blown by bypass air through special tubes from the area above the bathtub, which is inaccessible to drip entrainment.

Claims (6)

1. Electrocatcher of galvanic aerosols, in the housing of which there is a collecting part, consisting of electrodes of alternating polarity, characterized in that the electrodes consist of vertical plates with ribs perpendicular to them and arranged parallel to each other so that the edge of the electrode is of the same polarity located between the edges of the electrode of a different polarity. 2. Electrocatcher according to claim 1, characterized in that the bottom of the housing contains grooves with a slope for condensate drain. 3. The electrocatcher according to claim 1, characterized in that the electrodes are attached to the housing with studs mounted on one side of the electrodes, and on the other hand, through holes for mounting on insulators. 4. Electrocatcher according to claim 3, characterized in that the insulators on the outside are provided with side covers that are hermetically connected to the housing, which in the upper part contain openings with tubes. 5. Electrocatcher according to claim 3, characterized in that the insulators are made in the form of plates. 6. Electrocatcher according to claim 5, characterized in that the insulators are mounted on the front and rear walls of the housing using racks.