RU86490U1 - ELECTRIC FILTER - Google Patents

Abstract

An electrostatic precipitator consisting of a housing, precipitation electrodes made of pipes, and corona electrodes, which consist of alternating sections made in the form of rectilinear sections L2 and sections L1 made in the form of a spring, with the total length of the corona elements L, the distance between the turns of the spiral D depend on the parameters of the cleaned dust and gas stream and are in the ranges: L1 = 0.1 ... 0.5 m; L2 = 0.1 ... 0.5 m; D = 10 ... 20 d1, where D is the inner diameter of the precipitation electrode, d1 is the diameter of the rectilinear portion of the corona electrode, characterized in that the sections L1 are made in the form of conical springs with the smallest coil diameter d = 0.1 ... 0.5D and the largest diameter turn dmax = 0.5 ... 1D.

Description

The claimed utility model relates to electrostatic precipitators - apparatus for cleaning gases from suspended particles in various industries, in particular non-ferrous metallurgy, in electrode and other industries.

Known, selected as the closest analogue, an electrostatic precipitator consisting of a housing, precipitation electrodes made of pipes, and corona electrodes consisting of alternating sections made in the form of straight sections L2 and sections L1 made in the form of a coil spring, with the total length of the corona spring elements L, the diameter of the spiral d, the distance between the turns of the spiral D depend on the parameters of the cleaned dust and gas stream and are in the ranges: L1 = 0.1 ... 0.5 m; L2 = 0.1 ... 0.5 m; d = 0.1 ... 0.5D; D = 10 ... 20 d1; where D is the inner diameter of the precipitation electrode, d1 is the diameter of the rectilinear portion of the corona electrode (RF patent for the invention No. 2337746, class IPC B01D 35/06, publ. 10.11.2008 Bull. No. 31).

The disadvantage of this electrostatic precipitator is the weak electromagnetic field created by the cylindrical coils of the springs, which leads to poor-quality cleaning of the bedding.

The technical result that can be obtained in the claimed utility model is to increase the degree of gas purification.

The specified technical result is achieved in that in an electrostatic precipitator consisting of a housing, precipitation electrodes made of pipes, and corona electrodes, which consist of alternating sections made in the form of straight sections L2 and sections L1 made in the form of a spring, and the total length of the corona elements L, the distance between the turns of the spiral D depend on the parameters of the cleaned dust and gas stream and are in the ranges: L1 = 0.1 ... 0.5 m; L2 = 0.1 ... 0.5 m; D = 10 ... 20 d1, where D is the inner diameter of the precipitation electrode, d1 is the diameter of the rectilinear portion of the corona electrode, sections L1 are made in the form of conical springs with the smallest coil diameter d = 0,1 ... 0,5D and the largest coil diameter dmax = 0 , 5 ... 1D.

The claimed utility model is illustrated using the drawings shown in figures 1, 2.

In this case, FIG. 1 is a general view of the electrostatic precipitator, and FIG. 2 is a corona element.

Figure 1 and 2 adopted the following notation:

1 - electrostatic filter housing;

2 - precipitation electrode;

3 - corona elements;

4 - rectilinear section of the corona element;

5 - section of the corona element - a coil spring;

6 - load for tensioning the corona element.

D is the inner diameter of the precipitation electrode;

L is the total length of the corona elements;

L2 is the length of the rectilinear portion of the corona element;

L1 is the length of the section of the corona element is a coil spring;

d is the diameter of the smallest coil of a conical spring;

dmax is the diameter of the largest coil of the conical spring;

d1 is the diameter of the rectilinear portion of the corona element;

D is the distance between the turns of the coil spring.

The functioning of the proposed electrostatic precipitator is as follows.

A gas containing particles enters the electrostatic precipitator housing (1) and then passes through a system of corona and tubular precipitation electrodes. At the entrance to the precipitation electrodes, in the rectilinear section of the corona electrode, when a high voltage is applied, a corona discharge occurs, due to which the passing particles acquire a charge and partially precipitate in the zone of this section. Next, the particles together with the gas enter the area of the area of the corona electrode in the form of a conical spring. Due to the fact that the smallest diameter d of the conical spring can be 0.1 ... 0.5D, and the largest diameter dmax can be 0.5 ... 1D, where D is the internal diameter of the precipitation electrode, and the coil of the spring is located close to each other, there is no corona charge here, and the electric field strength will be much higher in the zone surrounding the coil with the largest diameter dmax. With increased tension, the efficiency of dust collection increases. As the dust-gas stream passes through the section of the conical spring (5), in addition to particle capture, partial recombination of charged particles can occur. At the same time, they become larger, but lose their charge - they are neutralized. Therefore, to recharge particles, a spring should be made - conical. Then the dust and gas stream enters again into the zone of the rectilinear section (4) of the corona electrode, where the particles are recharged. Further, the process is repeatedly repeated. As a result, a more efficient deposition of charged dust particles occurs, since approximately half the path in the electrostatic precipitator is affected by an electric current of increased tension.

It is known that the charging time of dust particles in the field of corona discharge of electrostatic precipitators is approximately 0.1 s. During this time, particles are charged on average 95%, which allows for efficient dust collection.

If the speed in the electrostatic precipitators is in the range of 0.8 ... 1.5 m / s, the length of the rectilinear section is determined by the charging time of 0.1 s and amounts to 0.15 m. When collecting dust with a high concentration of particles, the charging time will increase to approximately 0.3 s and the length L2 will also increase and will be approximately 0.24 ... 0.45 m.

In electrostatic precipitators with tubular precipitation electrodes, wire is used as corona electrodes. In this case, the ignition voltage of the corona is at the level of 25 kV. When this wire is twisted into a coil spring with closely spaced turns D = 10 ... 20 d1, experiments show that the mutual screening of the turns and coronation ceases. The electric field in the area of the spiral becomes electrostatic. Such a field breaks through at a higher voltage, and therefore, due to an increase in breakdown tension, the distance between the conical spring and the precipitation electrode can be reduced, which allows an increase in the degree of gas purification.

Industrial production of the proposed electrostatic precipitator does not require the development of new technologies, since the winding of the spring can be performed by known means.

Claims (1)

An electrostatic precipitator consisting of a housing, precipitation electrodes made of pipes, and corona electrodes, which consist of alternating sections made in the form of rectilinear sections L2 and sections L1 made in the form of a spring, with the total length of the corona elements L, the distance between the turns of the spiral D depend on the parameters of the cleaned dust and gas stream and are in the ranges: L1 = 0.1 ... 0.5 m; L2 = 0.1 ... 0.5 m; D = 10 ... 20 d1, where D is the inner diameter of the precipitation electrode, d1 is the diameter of the rectilinear portion of the corona electrode, characterized in that the sections L1 are made in the form of conical springs with the smallest coil diameter d = 0.1 ... 0.5D and the largest diameter turn dmax = 0.5 ... 1D.