RU2136381C1 - Electric precipitator - Google Patents

Abstract

FIELD: gas cleaning. SUBSTANCE: precipitator has case and sets of receiving and discharge electrodes building up electric field; corona-discharge members are installed at field entrance. Distance of these members from discharge electrodes makes up 1.5-1.7 of discharge distance. Corona-discharge members are mounted at entrance and exit of electric field, as well as between receiving electrodes through field length. EFFECT: improved efficiency of gas cleaning and simplified design of precipitator. 3 cl, 2 dwg, 1 tbl

Description

 The invention relates to electric cleaning of gases, in particular to electrostatic precipitators and dust collectors for cleaning gases from dust in various industries.

 A device is known in which the gases to be cleaned are previously passed through two parallel-mounted short-field electrostatic precipitators — a coagulator. One of the electrostatic precipitators operates with a negative corona, and the other with a positive one; as a result, suspended particles receive charges of different signs, coagulate, and then go to a dust collector. A device is also known in which the electrostatic precipitator-coagulator is supplied with alternating current of high voltage and low frequency, and coarsened particles are sent to a dust collector (Upsov V.N., Valdberg A.Yu. Preparation of industrial gases for cleaning. M. Chemistry, 1975, 49 - 50).

 The disadvantages of these devices include the fact that they consist of two separate devices: a coagulator and a dust collector, which increases their cost, and their degree of purification is insufficient.

 Closest to the proposed technical solution is an electrostatic precipitator, in the housing of which, at the entrance to the electric field formed between the corona and precipitation electrodes, a grounded perforated electrode is installed. The corona electrodes are tensioned using an electric motor and pulleys (UK patent N 1364029 CL B 03 C 3/14).

 The disadvantages of this solution include the low efficiency of gas purification and the complexity of the design solutions of the system of corona (discharge) electrodes.

 The proposed technical solution eliminates these disadvantages.

 The aim of the invention is to increase the efficiency of gas purification and simplify the design of the electrostatic precipitator.

 The goal is achieved by the fact that in the proposed electrostatic precipitator, which includes a housing, a system of precipitation and corona electrodes with an electric field, corona elements located 1.5 to 1.7 from the discharge distance are installed from the corona electrodes before entering the electric field.

 In addition, the corona elements are installed at the end of the electric field and in the row of precipitation electrodes along the field length.

In FIG. 1 shows the proposed electrostatic precipitator, which consists of a housing 1, grounded precipitation electrodes 2 and corona electrodes 3 connected to the negative polarity of the high voltage power source. At the entrance to the electrostatic precipitator, positively charged needle-shaped corona elements 4 are installed, which are located from the corona electrodes 3 by a distance (H ₁ ) of 1.5 - 1.7 from the discharge distance H ₀ (the distance between the corona 3 and precipitation 2 electrodes).

 In FIG. 2 shows the location of the corona elements in front of the entrance to the electric field, along the length of the latter along the gas stream and at the end of the field.

 The electrostatic precipitator works as follows.

 Dusty gas initially enters the zone of the positive corona, and the particles are positively charged. Then it enters the zone of the negative corona, where coagulation of particles and their deposition take place. Coarse particles are deposited on the precipitation electrode 2 more efficiently.

 Tests conducted in laboratory conditions have confirmed an increase in the efficiency of gas purification in the electrostatic precipitator by no less than 10%.

 The table gives the rationale for the proposed ratios of discharge distances.

 As can be seen from the table, the optimal ratio of the sizes of the distance of the corona elements from the corona electrodes to the discharge distance is 1.5 - 1.7. This allows you to increase the efficiency of gas purification in the electrostatic precipitator by 10%. The proposed electrostatic precipitator is easier to manufacture compared to the prototype.

Claims (3)

 1. An electrostatic precipitator, including a housing and systems of precipitation and corona electrodes with an electric field, characterized in that before it enters the electric field corona elements are installed, located from the corona electrodes by a distance of 1.5 - 1.7 from the discharge distance.  2. The electrostatic precipitator according to claim 1, characterized in that the additional corona elements are installed at the end of the electric field.  3. The electrostatic precipitator according to claim 1 or 2, characterized in that the additional corona elements are installed along the length of the electric field in the row of precipitation electrodes.

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