SU906595A1 - Centrifugal separator for separating dust from gas - Google Patents

Description

(54) CENTRIFUGAL SEPARATE DUST FROM GAS

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The invention relates to a technique for the purification of industrial gases or air from particles suspended in a gas and can be used in various industries of the national economy, for example, in mechanical engineering.

A centrifugal gas-dust separator is known, including a housing with an inlet side and outlet axial nozzles for gas, a hollow rotor with a radial channels inside the walls of the rotor, the cavity of which communicates with the outlet axial nozzle, and an adjustable guide device located in front of rotor and turning the gas flow from the inlet in the direction of rotation of the rotor 1.

However, the known device cannot trap fine dust of 10 microns in size, as a result of which the required gas cleaning efficiency is not achieved.

The purpose of the invention is to increase the efficiency of gas cleaning from dust due to the quenching of the kinetic energy of dust particles.

The goal is achieved by the fact that in a centrifugal separator of dust from gas, including a housing with inlet side and outlet axial nozzles for gas, a hollow rotor inside the housing has radial channels in the rotor walls, the cavity of which communicates both the outlet axial nozzle and adjustable a guiding device placed in front of the rotor and turning the gas flow from

10 of the inlet nozzle in the direction of rotation of the rotor, the adjustable guide device is made of a series of curved blades fixed with the possibility of individual rotation, and is placed in the inlet nozzle.

FIG. 1 shows the dust separator from the gas, a cross-section; in fig. 2 - the same, longitudinal section; in fig. 3 is a diagram of the forces acting on the dust particle trapped in the rotor channel.

20 The centrifugal radial separator for dust from gas consists of a rotor 1, having a large number of radio channels for the Lro gas flow, enclosed in the housing 2, in the upper part of which there is a gas

a hole with an expanding nozzle, and in the lower part - a dust storage bin with a hatch for unloading it. At the inlet of the housing is mounted on a hinge rotary jet apparatus 3. Coaxially the rotor is rigidly connected to the housing 2 of the fan 4. The rotor and the fan are rotated by the electric motor 5.

Dust separator works as follows.

When the fan 4 and the rotor 1 rotate by the electric motor 5, the dust-laden gas is sucked in by the fan 4 through the inlet of the housing 2. In the expanding housing nozzle, the gas loses part of its speed and already at a reduced speed enters the jet apparatus 3, where dust particles lose part of their kinetic energy and together with the gas, they change the direction of motion in such a way that the dust particles closest to the rotor 1 move relative to the rotor sidewall. In this case, the movement of gas with dust particles and the rotation of the rotor coincide in direction. Next, the flow of gas, the circumferential rotor 1, passes through the channels of the rotor. In doing so, the gas attempts to entrain the dust particles, creating a pressure force FQ on the dust, which is a component of the main pressure force of the gas F ;. The force Fj promotes the ingress of dust particles into the rotor channels. But the rotating rotor, in contact with the dust particle on the wall of the gas passage channel, imparts inertial forces to the dust particle: F o op is the Coriolis inertia force and Pc is the centrifugal inertia force. In addition, the rotor acts on the particle by the force of the impact of the rood. All forces are applied at one point. As a result of the addition of all forces, one resultant force R, which is the geometric sum of two resultant forces, flows out; RFts-lFd - the resultant forces of Ru + Rd and Cgsch-Rd-Good - resultant forces of Rd and Air.

Thus, the force contributes to the ejection of dust particles from the rotor channel in the direction of the housing 2. Hitting the housing 2, the dust particle loses a significant part of the kinetic energy received from the rotor and drops out of the gas stream into the storage bin of the housing 2. The dust cleared gas passes through the rotor and is thrown out by the fan. The rotor 1 cannot hold up the gas, since the rotational speed of the rotor is extremely small in order to create such a centrifugal force acting on the gas molecule that would overcome the pressure of the gas itself.

Purification efficiency is 83% with air dusting of 80 g / m and containing particles up to 10 microns in it.

Claims (1)

1. USSR author's certificate in application number 2728J39 / 26, cl. B01 D 46/26, 1980.