RU2346726C1 - Dust collection system - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: dust collection system comprises source of gas subject to treatment, fan, pipelines and two dust collectors on opposite twisted gas flows, every of which is equipped by conical bunker, upper tangential inlet nozzle, inlet vortex, dust baffling conical orifice, with axial outlet nozzle of treated gas and dust exhaust nozzle, in which rotary valve is installed. The novelty here is equipping of dust collection system pipelines by gate valves and arrangement of conical bunker of the first dust collector with nozzle of dust and gas mixture exhaust, besides, source of gas subject to treatment is connected to inlet of fan, delivery nozzle of which is connected to inlet tangential nozzle of the first dust collector and via gate valves to inlet swirlers of the first and second dust collectors.

EFFECT: higher efficiency of dusty gas treatment.

2 cl, 1 ex, 1 dwg

Description

The invention relates to the purification of gas and can be used in the chemical, food, woodworking industries, the production of building materials and products, and in other industries where it is necessary to clean the exhaust gases from fine dust particles.

A known dust collection system containing a source of gas to be purified, a fan and two vortex inertial dust collectors on counter swirling gas flows, each of which is made in the form of a cylindrical body with a conical hopper, with an upper tangential inlet pipe, with an inlet swirl in the second lower inlet pipe with a dust collection conical a washer on the outer surface of the lower nozzle, with an axial outlet nozzle and with a dust outlet in which the lock gate is installed. In this case, the source of the gas being cleaned, the tangential inlet pipe, the cylindrical body, the axial output pipe of the first dust collector, the fan, the tangential inlet pipe, the cylindrical body and the axial output pipe of the second dust collector are connected in series. The fan outlet is connected directly to the input swirl of the second dust collector, the dust outlet of which is connected directly to the input swirl of the first dust collector (see the description of the invention to patent RU No. 2137528, 1999).

The disadvantages of the known system are the lack of organized suction of the dust and gas mixture from the conical hopper of the first dust collector, which does not allow to increase its efficiency, and gas flows with the same dust concentration to the upper tangential inlet and to the input swirl of the second dust collector, which reduces its efficiency.

The task of the invention is to develop a dust collection system that provides increased cleaning efficiency of dusty gas, especially containing highly dispersed particles.

The essence of the invention lies in the fact that the dust collection system containing a source of gas to be cleaned, a fan, pipelines and two dust collectors on counter swirling gas flows, each of which is made in the form of a cylindrical body with a conical hopper, an upper tangential inlet pipe, an inlet swirl placed in the lower inlet pipe, and dust cone washer on its outer surface, with an axial outlet pipe of purified gas and a dust outlet in which the lock is installed creat, differs from the closest analogue in that the pipelines are equipped with shutters, and the conical hopper of the first dust collector is made with a nozzle of the outlet of the dust and gas mixture, while the source of the cleaned gas is connected to the inlet of the fan, the discharge nozzle of which is connected to the inlet tangential branch of the first dust collector and through the shutters - with inlet swirls of the first and second dust collectors, the outlet pipe of the dust and gas mixture from the conical hopper of the first dust collector is connected to the tangential through the damper the inlet nozzle of the second dust collector, the axial outlet of which is connected through the damper to the fan inlet, and the axial outlet of the first dust collector is in communication with the atmosphere.

Preferably, the ratio of the diameters of the cylindrical bodies of the first and second dust collectors, respectively, is 1: (0.5 ÷ 0.8).

The proposed invention allows, through organized suction of the dust and gas mixture from the conical hopper of the first dust collector, to increase its efficiency, by connecting the outlet of the dust and gas mixture from the conical hopper of the first dust collector to the upper tangential inlet of the second dust collector, to provide gas flows with different dust concentrations and thereby ensure increasing the efficiency of the second dust collector. This increases the efficiency of the dust collection system as a whole.

The invention is illustrated in the drawing, which schematically shows the proposed dust collection system.

The dust collection system contains a source 1 of purified gas, a fan 2 and two vortex inertial dust collectors 3 and 4 on counter swirling gas flows, each of which is made in the form of a cylindrical housing 5 with a conical hopper 6, an upper tangential inlet pipe 7, an inlet swirl 8, located in a lower inlet pipe 9, on the outer surface of which along the axis of the housing 5 there is a dust cone washer 10, with an axial outlet pipe of the cleaned gas 11 and with a dust outlet 12 in which Yuzov shutter 13. Pipelines are provided with flaps 14-17. The conical hopper 6 of the first dust collector 3 is made with the outlet pipe of the dust and gas mixture 18.

The dust collection system operates as follows.

The dusty gas stream from the source 1 through the pipeline by the fan 2 is fed to the tangential inlet pipe 7 of the first dust collector 3, through the pipeline with an open damper 15 to the inlet swirler 8, located in the second inlet pipe 9 of the first dust collector 3, and through the pipeline with an open damper 16 a swirler 8 located in the second inlet pipe 9 of the second dust collector 4. The gas stream cleaned in the dust collection system from the axial outlet pipe 11 of the first dust collector 3 is released into the atmosphere. From the hopper 6 of the dust collector 3, the dust and gas mixture is sucked through the pipe 18, which is supplied through the pipeline with the open shutter 17 to the upper tangential pipe 7 of the dust collector 4. The cleaned gas from the axial outlet pipe 11 of the dust collector 4 is fed through the pipeline with the open shutter 14 to the input of fan 2.

With the proposed arrangement of elements with shutters 15 and 16, the flow rate of gas supplied to the input swirls 8 of dust collectors 3 and 4 is regulated. The shutters 14, 16 and 17 provide the ability to connect and disconnect the dust collector 4, and also regulates the volume of dust and gas mixture sucked from the conical hopper 6 dust collector 3.

The organization of the suction of the dust-gas mixture, preferably from the upper part of the hopper 6 of the first dust collector 3, increases the vacuum in it, which intensifies the processes of coarsening of finely dispersed dust particles, dropping them to the walls of the housing 5 and increases the rate of dust deposition into the hopper 6. In this case, the dust collector sucked from the hopper 6 3 the dust and gas stream is effectively cleaned in the dust collector below 4. The supply of dusty gas to the inlet swirler 8 of the dust collector 4 from the fan 2 allows it to be reduced oprotivlenie during the purification of dust-gas mixture sucked out of the hopper 6 of the dust collector 3. The effluent from the axial pipe 11 of the dust collector 4, a gas stream with a low content of dust enters the fan inlet 2 for recirculation.

All the above arrangement conditions contribute to an increase in the degree of gas purification before being discharged into the atmosphere.

By calculation and experimentally, the optimal ratio of the inner diameters of the cylindrical bodies 5 of the first 3 and second 4 dust collectors was established, which is 1: (0.5 ÷ 0.8), respectively. With this ratio, an optimal mode of cleaning the dust and gas mixture, sucked from the hopper 6 of the dust collector 3, and returning the purified gas to the inlet of the fan 2 is ensured.

Example.

The proposed dust collection system was used to capture coke dust with an initial concentration at the system inlet of 15-25 g / m ³ , while the content of coke dust particles with sizes up to 15 μm reached 37%. At the exit from the system, the concentration of dust particles was about 1-2 g / m ³ , and the content of particles with a size of up to 15 μm was less than 18%.

The diameter of the cylindrical body of the dust collector 3 was 600 mm, and the diameter of the cylindrical body of the dust collector 4 was 400 mm, respectively.

Thus, the claimed invention improves the efficiency of purification of exhaust gases, including from fine dust particles.

Claims (2)

1. A dust collection system containing a source of gas to be purified, a fan, pipelines and two dust collectors on counter swirling gas flows, each of which is made in the form of a cylindrical body with a conical hopper, an upper tangential inlet pipe, an inlet swirler located in the lower inlet pipe, and a dust collector a conical washer on its outer surface, with an axial outlet nozzle of purified gas and a dust outlet in which a lock gate is installed, characterized in that the pipelines are They are removed by flaps, and the conical hopper of the first dust collector is made with a dust and gas mixture outlet pipe, while the source of gas to be cleaned is connected to the fan inlet, the discharge pipe of which is connected to the inlet tangential branch of the first dust collector and through the shutters with inlet swirls of the first and second dust collectors, the dust and gas mixture outlet pipe from the conical hopper of the first dust collector through the shutter is connected to the tangential inlet pipe of the second dust collector, the axial output pipe whose window is connected through the damper to the fan inlet, and the axial outlet pipe of the first dust collector is in communication with the atmosphere. 2. The dust collection system according to claim 1, characterized in that the ratio of the diameters of the cylindrical bodies of the first and second dust collectors, respectively, is 1: (0.5 ÷ 0.8).