SU1558494A1 - Cyclone-dust collector - Google Patents

Abstract

The invention relates to centrifugal type dust collectors and can be used in the chemical, textile, construction and other industries that require dry gas cleaning from suspended solids. The aim of the invention is to increase the efficiency of gas cleaning from dust by maintaining the twist of flow over the entire height of the apparatus. The cyclone dust collector consists of a cylindrical body 1 with a lower conical part 2, an inlet 3 and exhaust 4 nozzles and a pre-separation chamber 6 installed outside the body. Part of the dusty gas is fed through the central pipe 9, on which the nozzles 11 with slotted windows are installed, above the slotted windows 12 there is a swirler 10, the lower end of the nozzle is lowered to the conical part 2 of the apparatus and the disk 13 is fixed to it with a central cone 14. Maintaining an even twist the entire height of the cyclone dust collector leads to a constant separation intensity in height, which increases the intensity of gas cleaning. 1 il. 1 tab.

Description

The invention relates to centrifugal dust collectors and can be used in the chemical, petrochemical, textile, food industries, construction materials and other industries.

The aim of the invention is to increase the efficiency of gas purification by maintaining the flow twist along the entire height of the cyclone.

The drawing schematically shows the proposed cyclone dust collector.

The cyclone dust collector comprises a cylindrical body 1 with a lower conical part 2, an inlet tangential pipe 3 and an axial exhaust pipe 4. The main separation chamber 5 is connected to the preliminary separation chamber 6 (one preliminary separation chamber is shown) by means of inclined nozzles 7 and 8 of the first and second tiers installed inclined tangentially so as to create a flow rotation in the same direction as the tangential inlet pipe 3. The pipes 7 are located above the tier of the pipes 8. Inside With the axial exhaust pipe 4, a coaxial pipe 9 is installed, the inlet end of which is connected to the inlet pipe 3. A swirler 10 is installed in the pipe 9. Below the swirler 10, nozzles 11 are installed on the pipe with slotted windows 12 of a triangular, trapezoidal or other shape of a cross-section increasing from top to bottom for uniform filing a swirling flow at the bottom of the separation chamber. At the lower end of the nozzle, lowered to the conical part 2, a disk 13 is installed with a central cone 14 facing upward.

It is possible to adjust the flow rate through the slotted windows 12 by means of an additional coaxial rotary cup 15 mounted on the disk 13 with a small gap outside the pipe 9 and also made with slotted windows, respectively, to the windows 12. The cup 15 is rotated by a gear 16 with a handle.

The transmission can be gear, worm, etc. Dust is removed from the apparatus through the nozzle 17 and from the bottom of the conical part 2.

Cyelone dust collector operates as follows.

The dusty stream is supplied to the cyclone dust collector by the main part through the inlet pipe 3, and also through the central ⁵ pipe 9. Through the tangential inlet pipe 3, the swirling stream enters the preliminary separation chamber 6, where the largest dust is separated through the tangential inclined pipes 7 and 8, 1C receiving additional rotation into the chamber 5 of the main separation. Here, just as in the pre-separation chamber, under the action of centrifugal forces, solid particles are discarded to the wall of the housing 1 and, lowering, are discharged through the conical part 2, and the dust-free gas stream is removed through the exhaust pipe 4. A part of the gas stream is taken from the pipe 3, through a pipe 9 passes through a swirler 10, swirling the flow in the same direction as in the separation zone. Then it enters through the slotted windows 12 into the separation zone, twisting the main stream. However, due to the presence of a disk 13 with a central cone 14, the direction of this flow is radial, and it does not penetrate into the discharge zone and does not cause secondary ablation of dust. The dust-free total gas stream leaves the apparatus through the exhaust pipe 4.

In the proposed design, in contrast to the known ones, intensive separation occurs over the entire height of the apparatus, due to the supply of an additional swirling gas flow through the slotted windows 12. The flow through these windows can be adjusted by rotating 35 to a certain angle with the help of the drive 14 glass 15 with slotted windows. At the same time, the windows of the pipe 9 partially overlap the nozzle, reducing the flow of gas coming from the pipe 9 into the separation chamber 5.

Thus, due to the uniform twisting of the gas flow along the height of the apparatus, the most complete separation of the gas from the gas occurs.

The result of.. · Laboratory tests proposed !! '· l, piclon and known are given a ’'

Cyclone Consumption, and ³ / h { Dust concentration. g / m ³ The efficiency of cleaning,% on the. inlet at the exit 1 2 3 4 5 Famous 0, OS 7 15.0 0.285 by 1 0,0 (: Oh a 0.166 98.0 0.016 10.0 0.150 98.5 Proposed 0.007 15.0 0.150 ^ 9.0 0,0.11 8.3 0,091 . · '? j 0.016 10.0 0.051 99.5

The tests were carried out on limestone dust 050 = 9.7 mm in three modes for gas flow, pressure loss did not exceed 250 mm water column. The dustiness of the air was determined by external filtration.

Claims (1)

Claim A cyclone dust collector comprising a cylindrical conical body with a tangential inlet pipe, an axial exhaust pipe 10 cuttings, a pipe placed in it, the inlet end of which is connected to the inlet pipe, and the outlet end is placed along the cyclone axis and equipped with a swirl, concentric annular pre-separation chambers installed outside the body connected to the housing by inclined nozzles and having a dust outlet, characterized in that. that, in order to increase the efficiency of gas purification by maintaining uniform twist along the entire height of the cyclone, the pipe is equipped with a cylindrical nozzle mounted at its outlet end under the swirl with slotted windows of increasing • ultra-down section, the lower end of the nozzle is lowered to the conical part of the body, and a disk with with a central cone facing upward, on the disk outside the nozzle, a rotary cup is coaxially mounted, made with slotted windows coinciding with the nozzle windows.