RU2135296C1 - Electric filter - Google Patents

Abstract

FIELD: cleaning of gas from dust. SUBSTANCE: electric filter includes case, system of corona-forming electrodes and protective elements manufactured in the form of identical blade of wing profile and system of precipitation electrodes. Wing blades having sharp rear edges are so distributed in active zone of electric filter that they form flat grid of profiles in plane passing along gas flow perpendicular to precipitation electrodes. Its position is set by angle of installation of profile and angle of attack of profile. Manufacture of corona-forming electrodes in the form of wing profile leads to more uniform distribution of intensity in active zone of electric filter. Making of protective elements from dielectric, for example, fluoroplastic and their distribution in the form of grid of profiles in interelectrode space contributes to increase of its resistance. Usage of corona-forming electrodes and protective elements in the form of wing profile with sharp rear edges diminished resistance to gas flow, enhances carrying capacity of filter and ensures effective cleaning of gases from dust. EFFECT: enhanced carrying capacity of filter and provision for effective cleaning of gases from dust. 2 cl, 1 dwg

Description

 The invention relates to a device for cleaning dusty gases in electrostatic precipitators and can be applied at enterprises of the metallurgical, chemical, oil refining industries and other industries to increase the degree of purification of exhaust gases.

 A device for dedusting air is known, in which the corona electrode is made in the form of a needle and is blown cleaned by air, thereby increasing its saturation with ions flowing from the corona electrode. Increasing the density of the space charge contributes to a more efficient purification of air from contaminants.

 / US, patent N 5332425, B 03 C 3/41, 1994 /.

 A disadvantage of the known device is the low productivity of the cleaning process.

 A device for cleaning dusty gases in electrostatic precipitators is also known, including channels from plate-like precipitation electrodes, between which corona electrodes and protective elements from plates with paired leading edges are located one after another.

 / US, U.S. Patent No. 4,381,927, Ch. 55-138, 1983 /.

 The disadvantages of this device are disruption of the gas flow from the surface of the protective elements and the formation of vortices, which reduce the efficiency of dust deposition.

 The problem solved by the described invention is to increase the efficiency of dust collection in the electrostatic precipitator, achieved by increasing the drift velocity of the aerosol particles to the precipitation electrodes; increasing the density of the flow of ions flowing from the corona electrode; reducing the gas-dynamic resistance of the electrostatic precipitator.

 To solve this problem, in an electrostatic precipitator containing a housing, a system of corona electrodes with protective elements and a system of plate sedimentation electrodes, corona electrodes and protective elements are made in the form of identical wing profile blades with a sharp trailing edge and form in a plane along the gas flow perpendicular to the precipitation electrodes , a flat grid of wing profiles, in which the location of the profiles from the protective elements is obtained from the profile from the corona electrode Yelnia transfer an integer steps towards precipitation electrode defined by the angle profile setup between the selected direction and the chord of the profile. The profiles are set at an angle of attack between the velocity vector of the incident dust-gas gas flow and the chord of the profile.

The angle of installation of the wing profile between the chord of the profile and the direction of construction of the lattice of profiles is selected in the range of 0-90 ^o , the angle of attack between the velocity vector of the incoming gas flow and the direction of the chord of the profile is selected in the range of 0-40 ^o .

 The numerical values of the angles depend on the physical properties of the dust and gas stream, its speed, nature and concentration of the aerosol.

 The protective elements of the wing profile are made of a dielectric / for example, fluoroplastic /.

 The drawing schematically shows an electrostatic precipitator.

 The electrostatic precipitator contains a housing (not shown) in which the system of corona electrodes in the form of wing profile blades 1 with a sharp trailing edge 2 and plate-like precipitation electrodes 3 are located. The system of protective elements in the form of identical wing profile blades 4 forms together with the corona electrode in a plane passing along the gas flow perpendicular to the sedimentation electrodes, a flat profile grid in which the arrangement of the profiles from the protective elements is obtained from the profile from the corona electrode by transferring by an integer number of steps in the direction of the axis of the grating to the precipitation electrode, defined by the angle of installation of the profiles α between the selected direction and the chord of the profile. The profiles are positioned at an angle of attack β between the free-stream velocity vector and the profile chord.

 The optimal choice of the profile angle and angle of attack depending on the physical properties of the gas stream provides continuous gas flow around the wing profiles with a smooth exit of the jets from the sharp trailing edges 5 and 2.

 The electrostatic precipitator works as follows.

 When applying a high DC voltage to the corona electrode 1 on its sharp trailing edge 2, conditions are created for the occurrence of corona discharge. The dust and gas stream flowing around the corona electrode helps to equalize the distribution of the density of the space charge in the ionization zone near the sharp trailing edge of the electrode and, taking the charges along, increases their density in the interelectrode gap. Dust particles, falling in the area between the corona and precipitation electrode 3, are charged and under the action of electric forces move to the precipitation electrode.

 The action of the lattice of profiles 1 and 4 leads to an increase in the speed of the incident flow behind the lattice and the rotation of the flow towards the precipitation electrode. In this case, the static gas pressure decreases near the corona electrode and increases at the precipitation one. This positively affects the outflow of ions from the edge of the corona profile and the formation of a dust layer on the precipitation electrode. The layer is more dense.

 Thus, the lattice of wing profiles located in the oncoming dust and gas flow at the angle of installation of the profiles α and the angle of attack β contributes to the emergence of additional forces acting together with the electric on the aerosol particles and increasing the speed of their drift to the precipitation electrode.

 The manufacture of corona electrodes in the form of wing-shaped blades with a sharp trailing edge leads to equalization of the electric field in the active zone of the electrostatic precipitator at the same applied voltage, and the arrangement of corona electrodes and protective elements in a plane along the gas flow perpendicular to the precipitation electrodes is in the form of a flat the grating of the wing profiles increases the electrical resistance of the working gap.

 The use of corona electrodes and protective elements in the form of wing-shaped blades reduces the resistance to the gas flow, increases its throughput and ensures effective cleaning of gases from dust.

Claims (3)

 1. An electrostatic precipitator comprising a housing, a system of corona electrodes with protective elements and a system of plate sedimentation electrodes, characterized in that the corona electrodes and protective elements are made in the form of identical wing profile blades with a sharp trailing edge and form in a plane along the gas flow perpendicular to the precipitation electrodes, a flat grid of wing profiles, in which the location of the profiles of the protective elements is obtained by parallel transfer of the profile of the corona electrode and an integer number of steps in the direction of the precipitation electrode, specified by the angle of installation of the profile between the selected direction and the chord of the profile, while the profiles are positioned at an angle of attack between the velocity vector of the incident dust and gas flow and the chord of the profile. 2. The electrostatic precipitator according to claim 1, characterized in that the profile installation angle is selected in the range of 0 - 90 ^o , the angle of attack is in the range of 0 - 40 ^o .  3. The electrostatic precipitator according to claim 1, characterized in that the protective elements are made of dielectric.