RU2342975C1 - Dust-collecting system - Google Patents

Abstract

FIELD: motors and pumps.

SUBSTANCE: dust-collecting system includes the source of cleaned gas, pipelines, fan, two dust-collecting units installed at counter-current swirling flows of gas. Each dust-collecting unit is represented with the cylindrical body with the tapered hopper, the first tangential inlet nozzle, inlet swirler in the second inlet nozzle and dust extracting beveled washer installed on its outer surface. The body is also provided with axial outlet nozzle for the cleaned gas and dust discharge nozzle where flood-gate is installed. The system is also provided with the source of clean air, the chokes installed on the pipelines and separating concentrator including cylindrical swirling chamber linked with inlet chamber provided with tangential inlet. There is axial pipe in the swirling chamber to discharge gas flow with less dust concentration. The swirling chamber outlet is located at the opposite side from inlet chamber. Side nozzle is mounted on the surface of swirling chamber to discharge gas flow with higher dust concentration. Tapered hopper of the fist dust-collecting unit is provided with dust-laden gas outlet nozzle. Cleaned gas source is connected to the tangential inlet of separating concentrator having side nozzle connected to the tangential inlet nozzle of the first dust-collecting unit. The axial outlet nozzle of the first dust-collecting unit is linked with the suction nozzle of the fan. Clean air source is coupled with the pipeline provided with choke and with inlet swirler of the first dust-collecting unit. Besides, axial pipe of the separating concentrator is coupled with the pipeline provided with choke and with the pipeline connecting clean gas source with inlet swirler of the first dust-collecting unit. The dust-laden gas nozzle of the first dust-collecting unit is linked with the tangential inlet nozzle and inlet swirler of the second dust-collecting unit. The axial outlet nozzle of the second dust-collecting unit is provided with the suction nozzle of the fan.

EFFECT: effective cleaning if dust-laden gas flow containing highly-disperse particles.

3 dwg, 1 ex

Description

The invention relates to systems for gas purification and can be used in various industries - chemical, food, woodworking, building materials, which require the cleaning of exhaust gases from fine dust particles.

A known dust collection system containing a source of gas to be cleaned, a fan 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, with a tangential inlet pipe, with an inlet swirl in the second inlet pipe with a dust cone washer on it the outer surface, with an axial outlet pipe and with a dust outlet, in which the lock gate is installed. In this case, the outlet of the source of the gas being cleaned, the tangential inlet pipe, the cylindrical body, the axial inlet 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). This system is the closest analogue of the proposed technical solution.

A disadvantage of the known system is that it does not allow to achieve a high degree of purification of a gas containing highly dispersed particles.

The task of the invention is the ability to effectively clean the dust and gas stream containing fine particles.

The essence of the invention lies in the fact that the dust collection system contains a source of gas to be purified, pipelines, a fan 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, a first tangential inlet pipe, an inlet swirler in the second inlet pipe and dust cone washer on its outer surface, with an axial outlet nozzle of purified gas and a dust outlet in which the lock gate is installed. The dust collection system differs from the closest analogue in that it is equipped with a source of clean air, dampers installed on the pipelines and a separator-concentrator including a cylindrical vortex chamber in communication with an inlet chamber having a tangential inlet, while an axial pipe is installed in the vortex chamber to discharge the gas flow with a lower concentration of dust, the output of which is located on the side of the vortex chamber opposite to the input chamber, a side nozzle is located on the surface of the vortex chamber for a gas stream with a higher dust concentration, and the conical hopper of the first dust collector is equipped with a dusty gas outlet pipe, while the source of gas to be cleaned is connected to the tangential inlet of the separator-concentrator, the side pipe of which is connected to the tangential inlet pipe of the first dust collector, the axial outlet of which is connected to the suction a fan nozzle, and a clean air source is connected by a pipe provided with a damper to the inlet swirl of the first dust collector, with this axis The separator-concentrator tube is connected by a pipe equipped with a damper to a pipe connecting the clean gas source to the inlet swirl of the first dust collector, the dusty gas outlet of which is connected to the tangential inlet pipe and the inlet swirl of the second dust collector, the axial outlet of which is connected to the suction pipe of the fan.

The invention is illustrated in the drawing, where figure 1 shows a diagram of the proposed dust collection system, figure 2 is a front view in section of a separator-hub, shown in figure 1, and figure 3 is a top view thereof.

The dust collection system contains a source of gas to be purified 1, fan 2 and two dust collectors 3 and 4 on counter swirling gas flows, each of which is made in the form of a cylindrical body 5 with a conical hopper 6, a tangential inlet pipe 7, an inlet swirl 8 in the second inlet pipe 9, equipped with a dust cone washer 10, with an axial outlet pipe of the cleaned gas 11 and a dust outlet 12 in which the lock gate 13 is installed. The system contains six shutters 14 - 19, a clean air source 20 and will separate a spruce concentrator 21 including a vortex cylindrical chamber 23 connected to an inlet chamber 22 having a tangential input, a side pipe 24 and an axial pipe 25 for outputting the separated flows. In this case, the conical hopper of the first dust collector 3 is equipped with a nozzle for the exit of dusty gas 26.

The dust collection system operates as follows.

As can be seen in figure 1, the flow of dusty gas from the source 1 enters through a tangential input into the inlet chamber 22 of the separator-concentrator 21, from where it is supplied to the cylindrical vortex chamber 23, where it is separated (see Fig. 2, 3). An axial tube 25 is installed in the vortex chamber 23 for outputting a gas stream with a lower dust concentration, the outlet of which is located on the side of the vortex chamber opposite to the input chamber, and a side pipe 24 is located on the surface of the vortex chamber for outputting a gas stream with a higher dust concentration.

A gas stream with a higher concentration of dust from the side pipe 24 of the separator-concentrator 21 enters through the open valve 14 to the tangential inlet pipe 7 of the first dust collector 3, and a stream with a lower concentration of dust from the axial pipe 25 through the open valve 16 enters the inlet swirl 8 located in the inlet pipe 9 of this dust collector. At the inlet swirler 8 of the first dust collector 3, clean air is also supplied from the source 20 through the open damper 15. The stream of gas purified in the dust collector 3 from the axial outlet pipe 11 enters the suction pipe fan 2 and is released into the atmosphere. From the hopper 6 of the first dust collector 3, dusty gas is sucked out through a pipe 26, which through the open damper 17 enters the tangential inlet pipe of the second dust collector 4 and through the open shutter 18 to the inlet swirl 8 of this dust collector, and the stream of purified gas from the axial outlet pipe 11 and open the valve 19 enters the suction pipe of the fan 2 and is released into the atmosphere. The dust released in the dust collectors 3 and 4 is discharged through the sluice gates 13 installed on the dust exhaust pipes 12.

In the proposed dust collection system, the shutters 14 and 16 control the flow of two gas streams into the dust collector 3 from the separator-concentrator 21. The shutter 15 controls the supply of clean air to the dust collector 3, and the shutters 17, 18 and 19 provide a predetermined gas suction from the hopper 6 of the dust collector 3.

The proposed dusty gas purification system makes it possible to obtain two gas streams with different concentrations of dust particles in a separator concentrator, while coarsening of finely dispersed particles takes place, and direct these streams to the first dust separator 3 in such a way that a gas stream with a larger dust concentration and moves down a helix, and a gas stream with a lower dust concentration is connected to a stream of clean air and through the inlet swirler 8, located in the pipe 9, enters the cylindrical housing 5 of the dust collector 3 and moves upward along a helical line with a smaller twist radius than the flow received through the tangential pipe 7, i.e. its movement occurs near the axis of the dust collector 3. In this case, the direction of rotation of the two flows coincides. Under the action of centrifugal forces and with the positive effect of the specified upward flow, an effective separation of the dust particles introduced through the input swirler takes place, which are thrown onto the walls of the housing 5 of the dust collector 3, which then fall under the influence of gravity into the dust bin. At the same time, the percentage of capture of fine particles increases.

The organization of gas suction from the upper part of the hopper 6 of the dust collector 3 increases the vacuum inside the cylindrical chamber 5 of the dust collector 3, which intensifies the process of dropping dust particles to the walls of the cylindrical chamber 5 and increases the speed of their deposition into the hopper 6. At the same time, the dust suction from the hopper 6 of the dust collector 3 gas-air flow is effectively cleaned in the dust collector 4.

Example.

The proposed dust collection system was used to capture coke dust with an initial concentration of 7-14 g / m ³ at the system inlet, while the content of coke dust particles with a size of up to 15 μm at the entrance to the dust collection system reached 40%. At the exit from the system, the concentration of dust particles was 0.3-0.5 g / m ³ , and the content of particles with a size of up to 15 μm was less than 17%, and the capture of particles with a size of up to 5 μm was up to 10%.

Thus, the proposed system provides high efficiency for removing dust from contaminated gas, including fine particles.

Claims (1)

A dust collection system containing a source of gas to be purified, pipelines, a fan 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, the first tangential inlet pipe, an inlet swirl in the second inlet pipe and a dust collection conical washer on its outer surface, with an axial outlet pipe of purified gas and a dust discharge pipe in which a lock gate is installed, characterized in that it is provided with a source of clean air, flaps installed on the pipelines and a separator-concentrator including a cylindrical vortex chamber in communication with an inlet chamber having a tangential inlet, while an axial tube is installed in the vortex chamber for outputting a gas stream with a lower dust concentration, the outlet of which is located from the opposite from the inlet chamber side of the vortex chamber, on the surface of the vortex chamber there is a side pipe for outputting a gas stream with a higher concentration of dust, and the conical hopper of the first dust collector is equipped with a pat the outlet of the dusty gas, while the source of the gas to be cleaned is connected to the tangential inlet of the separator-concentrator, the side pipe of which is connected to the tangential inlet pipe of the first dust collector, the axial outlet pipe of which is connected to the suction pipe of the fan, and the clean air source is connected by a pipe equipped with a shutter, with the input swirl of the first dust collector, while the axial tube of the separator-hub is connected by a pipeline equipped with a damper to the pipeline, with Dinh source of clean gas to the inlet of the first swirler dust collector, the dust-laden gas outlet pipe which is connected to the tangential inlet port and the inlet of the dust collector of the second swirlers, axial outlet which communicates with the suction fan nozzle.

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