RU2211094C2 - Electric filter - Google Patents

Abstract

FIELD: electric cleaning of gases from dust in various branches of industry, specifically, in heat power, chemical, building materials industries, metallurgy. SUBSTANCE: electric filter includes body, corona-forming electrodes with corona-forming elements and precipitation electrodes. Each electrode contains precipitation elements hung from suspension beam and attached to shaking beam. Filter also has shock mechanisms to shake above-mentioned electrodes. Precipitation electrodes are made fast to suspension beam. End of suspension beam nearest to shock mechanism is lifted clear with respect to opposite end and shaking beam of precipitation electrode is displaced in plane of precipitation electrode from shock mechanism in direction of shock and is fixed by locating arm so that precipitation elements adopt position parallel to corona-forming elements. EFFECT: increased shaking efficiency and functional reliability of electric filter. 2 cl, 4 dwg

Description

 The invention relates to the electrical cleaning of gases from dust in various industries, in particular in the power industry, chemical industry, building materials industry, metallurgy.

 Known electrostatic precipitator from: Gas purification equipment. Catalog. Tsintimhimneftemash, M., 1988, pp. 4-7, including a housing, plate-like precipitation electrodes, the elements of which are suspended from a suspension beam with a fixed shaking beam.

 The electrostatic precipitator includes corona electrodes of a frame construction. Shaking of the corona electrodes is carried out by a hammer mechanism.

 The disadvantages of this filter include the insufficient efficiency of shaking the precipitation electrodes due to the loss of shock energy, which is spent on moving the shaking beam with the elements in the direction of impact in the plane of the electrode.

 Known design of an electrostatic precipitator from: Gas purification equipment. Catalog. Tsintihimneftemash, M., 1988, pp. 11-12, in which, to increase the effect of shock interaction, the shaking beam is eccentrically suspended with respect to the hammer. However, this design is functional only with the free installation of precipitation elements in the grooves of the shaking beam. In addition, after impact interaction, freely installed precipitating elements lose their guaranteed contact with the shaking beam, which reduces the reliability of shaking.

 Closest to the proposed device in terms of technical nature, the technical problem to be solved and the totality of common essential features is the device disclosed in SU 1717235 A1, 03.03.1992, 03 C 3/74, adopted as a prototype.

 According to it, the electrostatic precipitator contains a housing, corona electrodes with corona elements and precipitation electrodes, each of which includes precipitation elements suspended from a suspension beam and attached to a shaking beam, shock mechanisms for shaking said electrodes.

 In this electrostatic precipitator, the precipitating elements are displaced from the impact mechanism and, due to the stiffness of the elements, are guaranteed to contact the shaking beam. However, in this case, the alignment of the precipitation elements with the corona elements is violated, which leads to a violation of the uniformity of the electric field and, as a result, to a decrease in the degree of gas purification.

 The technical task of the claimed invention and the technical result achieved by solving it is to increase the efficiency of shaking the precipitation electrodes, to maximize the use and increase the active zone of the electrostatic precipitator, to increase the reliability of its operation.

 The specified technical result is achieved in that the electrostatic precipitator comprises a housing, corona electrodes with corona elements and precipitation electrodes, each of which includes precipitation elements suspended from the suspension beam and attached to the shaking beam from below, shock mechanisms for shaking the said electrodes. Precipitation elements are attached to the suspension beam rigidly. The end of the suspension beam closest to the shock mechanism of the suspension beam is raised relative to the opposite end, and the shaking beam of the precipitation electrode is displaced in the plane of the precipitation electrode from the shock mechanism in the direction of impact and is fixed by a latch to accept the position of the precipitation elements parallel or close to parallel to the corona elements .

In addition, in particular cases of the invention:
- the end of the suspension beam closest to the shock mechanism of the suspension beam is raised by means of a lifting-lowering device;
- the shock mechanism of shaking the corona electrodes is located on top.

 These features are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

 The possibility of carrying out the invention, characterized by the above set of features, as well as the possibility of realizing the purpose of the invention can be confirmed by the description of a possible design of the device made in accordance with the invention, the essence of which is illustrated by graphic materials.

 Figure 1 shows a longitudinal section of the proposed electrostatic precipitator.

 Figure 2 shows the support of the suspension beam of the precipitation electrode from the side of the percussion mechanism and the location of the suspension beam on it.

 In FIG. 3 shows the support of the suspension beam of the precipitation electrode on the opposite side of the impact mechanism and the location of the suspension beam on it.

 In FIG. Figure 4 shows the distribution of dust on the electrodes under mutually opposite impacts (indicated by arrows) over the electrodes, ensuring a uniform electric mode over the entire plane of the electrodes.

 The proposed electrostatic precipitator includes a housing 1, corona electrodes 2 with corona elements 4 and with a percussion mechanism 3 located on top. Also, the electrostatic precipitator includes precipitation electrodes. The design of the precipitation electrode consists of a suspension beam 5, precipitation elements 6 rigidly suspended to it and a shaking beam 7 attached to them from below, and also includes a shock (hammer) mechanism 8 and a clamp 9 of the shaking beam 7. The suspension beam 5 is raised from the side of the shock mechanism to the value of "a". The support of the suspension beam 5 of the precipitation electrode from the side of the percussion mechanism 8 can be adjustable by means of the lifting-lowering device 10.

 Shaking the precipitation electrodes in the proposed electrostatic precipitator is as follows.

 Usually, for example, in the design of the prototype, the precipitation elements are freely suspended, usually on bolts, to the suspension beam. As a result, during the shock action of the shock mechanism, there are displacements of the electrode plane, both in the direction of the shock, and low-frequency oscillations of the precipitation elements are possible, and as a result, the energy of the shock action of the shock mechanism is lost.

 To eliminate these losses and increase the efficiency of shaking, the shaking beam 5 in the proposed electrostatic precipitator together with the precipitating elements 6 fixed to it is raised by the value "a", which allows you to select all the gaps. With a further rise, the precipitating elements 6 will lose alignment with the corona elements 4, therefore, the shaking beam 7 by means of the retainer 9 is shifted away from the percussion mechanism in the direction of impact in the electrode plane until the alignment, or parallelism, of the precipitating elements 6 and the corona elements 4 is restored and fixed in this position. The precipitation electrode system thus acquires a rigid structure and works with increased shaking efficiency and degree of purification. The precipitation electrode, depending on the magnitude of the rise of the end of the suspension beam 5 "a" and depending on it the displacement of the shaking beam 7, acquires a different degree of rigidity, and therefore it becomes possible to control the level of shaking of the precipitation electrodes.

 An increase in the level of shaking of the electrodes, along with a toughening of the structure, is also due to a more complete impact interaction of the shock mechanism 8 and the shaking beam 7.

 Figure 2 shows a variant of the device for lifting-pulling 10 of the suspension beam 5, which allows, as necessary, depending on the type of dust, to achieve one or another stiffness of the precipitation elements 6 and thereby guarantee the shaking off of various types of dust. The hoisting device 10 may be a conventional threaded pair with a lock nut.

 The rigidity of fastening of each precipitation element 6 to the suspension beams 5 is achieved, for example, due to the presence of two fastening bolts instead of one, as in the prototype.

 Such a design of precipitation electrodes with a shaking system in combination with a corona shaking system from above allows achieving an increased degree of purification of the electrostatic precipitator. The proposed electrostatic precipitator due to the fact that the shaking of the electrodes is carried out from opposite directions (corona - from the top, and sedimentation - from the bottom) and with high efficiency has an increased level of breakdown voltage, as well as secondary dust removal is carried out more uniformly over the cross section of the electrostatic precipitator, which reduces its negative consequences on the degree of gas purification.

 In FIG. Figure 4 shows the distribution of dust on the electrodes under mutually opposite impacts (indicated by arrows) over the electrodes, ensuring a uniform electric mode over the entire plane of the electrodes. The distance "between" between the dust deposits after the impact is maintained along the height of the electrode systems, which ensures a stable electrical mode.

 This design of the electrostatic precipitator increases the reliability and efficiency of its work.

 The present invention is industrially applicable, since its manufacture does not require special equipment and new technology.

 The design of the Electrofilter device described in this example and depicted in graphic materials is not the only one possible to achieve the above technical result and does not exclude other variants of its manufacture containing a combination of features included in an independent claim.

Claims (3)

 1. An electrostatic precipitator comprising a housing, corona electrodes with corona elements and precipitation electrodes, each of which includes precipitation elements suspended from a suspension beam and attached to a shaking beam, shock mechanisms for shaking said electrodes, characterized in that the precipitation elements are fixed to the suspension beam , the end of the suspension beam closest to the shock mechanism of the suspension beam is raised relative to the opposite end, and the beam of shaking of the precipitation electrode is shifted to the plane and precipitation electrode by the hammer in the direction of impact and fixed clamp element for making the collecting position parallel corona elements.  2. The electrostatic precipitator according to claim 1, characterized in that the end of the suspension beam closest to the shock mechanism of the suspension beam is raised by means of a lifting-lowering device.  3. The electrostatic precipitator according to claim 1 or 2, characterized in that the shock mechanism of shaking the corona electrodes is located on top.

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