SU1766469A1 - Dynamical separator - Google Patents

Abstract

Use - gas cleaning from droplet moisture in industrial ventilation and air conditioning systems. The gas stream with droplet moisture enters the separator, contains rotating dmski 12 with paired notches 13, bridges 14 and tapping 15. At the expense of these elements, the colliding pairs of jets collide with subsequent coagulation. Drops are deposited on the blades in the form of a film. Through the confuser, the liquid enters the collection. 1 hp ff, 5 ill. entrance

Description

The invention relates to devices for the separation of aerodisperse systems and may find application in the purification of gases from dropping liquid, including fogs.

A device for cleaning gas from dust is known, comprising an inlet, a spiral-shaped housing, a rotor with blades mounted in the housing. The internal cavity of the housing is divided by a partition into channels ending in outlet pipes for dirty and clean gas (1), respectively.

The said device has a low degree of dust collection due to the absence of additional separation means on the conical part of the rotor.

The closest solution to the claimed technical essence is a dust collector for trapping solid particles from the dusty gas stream (2).

Said dust collector is made in the form of a centrifugal fan and is equipped with a conical rotating disk, on the outer surface of which blades are located.

A conical disk is mounted on the same shaft with the fan rotor and is located directly against its suction inlet. In front of the fan, next to its casing, a chamber is installed to trap solid particles separated from the gas.

This device also has an insufficient degree of gas cleaning from dust, due to the absence of additional funds that increase the degree of dust collection.

The purpose of the invention is to increase the efficiency of separation of droplet moisture by intensifying the process of coagulation of its particles.

This goal is achieved by the fact that in a separator dynamic, comprising a housing with inlet and outlet nozzles, a fan wheel with a drive, a conical separating rotor mounted at the wheel inlet, the surface of the conical rotor is formed by a system of blades installed with a gap relative to each other and offset adjacent blades in the tangential direction with the rotor facing a large base to the inlet nozzle.

In order to improve the process of coagulation of fluid particles, a variant is possible when the separator is equipped with an additional conical insert fixed with a base around the perimeter of the base of the conical rotor, and pairwise slits are made on the insert surface to form flanges directed inward to the insert.

1 schematically shows the proposed separator; figure 2 - rotor insert, made biconical; on fig.Z - angular profile blades; figure 4 - blades are flat, figure 5 - blades S-shaped profile.

The dynamic separator (Fig. 1) consists of a housing 1 with an inlet 2 and an outlet 3 with nozzles, 4 fan wheels with a step 5 on it and an actuator 6. A confuser 7 is installed in the housing 1, installed with a gap relative to the inlet 2. Around the gap with overlapping surfaces of the confuser 7 and the inlet nozzle 2, the annular oil sump 8 is located, having an outlet 9. On the hub 5 of the wheel 4 (or on the drive shaft 6) there is a conical rotor 10 facing the large base to the inlet nozzle 2,

0 The surface of the rotor 10 is formed by a system of separating blades 11 installed with a gap relative to each other and with the displacement of adjacent blades in the tangential direction (figure 2) to form 5 labyrinths.

The maze parameters are determined by calculation.

In the larger base of the rotor 10, disks 12 are placed, having pairwise slits 13 with bridges 14 between them and flanges 15 directed inwardly to the inside of the rotor.

The slits are designed to form collision jets,

5 As a result, coagulation of fluid particles occurs, which improves further separation.

Blades for separation and directional removal of droplet moisture from the stream can be applied to the angular profile, flat, S-shaped blades, etc. (Fig.3-5).

In addition to the described construction of a dynamic separator, it is possible that the rotor 10 is additionally equipped with a conical

5 insert 1 b, forming a single structure rotor - insert (bi conic). In this case, an additional conic insert 16 is fixed with a base around the perimeter of the base of the conical rotor 10, and pairwise slits 13 are made on its surface with jumpers 14 between them and flanging 15 directed inward to the insert towards each other.

The choice of rotor design 10 depends

5 from the physico-chemical properties of the separated dropping liquid.

The invention is not limited to the given examples of performance, there are other possible, within the limits of the materials presented, which would provide coagulation and inertial - centrifugal methods for the separation of aerodisperse systems.

Works separator dynamic as follows.

The gas stream containing the drop liquid (water, oil) flows through the inlet pipe 2 to the coagulation step. The latter are the disks 12, having pairwise notches 13 with bridges 14 between them and flanging 15, directed towards the inside of the rotor mutually towards each other.

Striking the surface of the disks 12, large drops of liquid, in the form of a film, are thrown by centrifugal forces on the confuser 7 and further outside the device. And the fine fractions, continuing their further movement, enter the gaps 13.

Due to the presence of the flanging 15, a collision of opposing pairs of gas flow jets inside the rotor 10 occurs. As a result, the particles of the liquid undergo coagulation. Under the action of the dynamic pressure of the gas, the enlarged liquid droplets are almost completely trapped by the conical rotor 10 due to the action of inertial forces with the corresponding parameters of the labyrinths formed by the separating blades 11.

Drops are deposited on the separating blades in the form of a film, which under the action of centrifugal forces through the confuser 7 enters the annular oil collector 8 and further to the drain 9.

In a variant of the design in which an additional conical insert 16 is used as a coagulation step, large drops of liquid, in contact with the surface of the insert, form a film that, under the action of centrifugal forces, through the confuser 7 enters the annular oil-

Bornik 8 and output. And the fine fractions, the passage through the perforations 13, having flanging 15, collide with each other and are enlarged. The enlarged liquid droplets are trapped by the disk 12, and the fine fractions are trapped by the rotor 10 with the corresponding parameters of the labyrinths formed by the separating blades 11.

Thus, the proposed device allows the use of a complex separation system, including a combination of inertial-coagulation phase separation method, which increases the degree of gas purification from liquid components, i.e. increases trapping rate of these components.

Claims (2)

1. A dynamic separator, comprising a housing with inlet and outlet nozzles, a fan-driven fan wheel, a conical separating rotor mounted at the wheel inlet, characterized in that, in order to increase the efficiency of the separation of droplet moisture by intensifying the process of coagulation of its particles, the surface of the conical rotor is formed by a system of blades installed with a gap one relative to the other and displacing adjacent blades in the tangential direction, while the rotor faces a large base to the inlet nozzle 2. A separator according to claim 1, characterized in that, in order to improve the process of coagulation of fluid particles, it is provided with an additional conical insert fixed with a base around the perimeter of the base of the conical rotor, and pairwise slits are made on the surface of the insert, forming flanges directed inward of the insert one towards the other. food Qbt.5 Fig ®ig, 5