RU162739U1 - EXPERIMENTAL INSTALLATION FOR CLEANING AIR FROM DUST - Google Patents

Abstract

An experimental installation for dust air purification, containing an inertial vortex dust collector with counter-swirling flows with a cylindrical body and a conical hopper for receiving trapped dust and with its outlet pipe from the hopper, with an axial outlet pipe for clean air, with an upper inlet pipe and with a lower inlet pipe for supplying a dust-air mixture to the dust collector, while at the output end of the lower inlet pipe a conical baffle plate is installed, the dust feeder is connected to the first pipe a wire, which is connected by its output to the upper inlet pipe of the dust collector and connected to a second pipe, inside which the first rotary damper is installed, while the second pipe is connected by its output to the lower inlet pipe for supplying the dust-air mixture to the dust collector, in addition, the installation contains axially connected in series dust collector nozzle, third pipeline, filter and fan with inlet and outlet nozzles, the installation contains fittings for connecting a control meter devices, characterized in that the cylindrical case of the dust collector is made of organic glass, the upper and lower inlet nozzles of the dust collector body are tangential, a snubber swirl is installed inside the upper input tangential nozzle, the first retractable gate is installed on the nozzle for collecting dust from the hopper, inside the first pipe is installed second rotary damper, the filter is made in the form of a bag filter with a conical hopper and a nozzle for collecting dust, on which anovle

Description

The utility model relates to techniques for cleaning air from dust and can be used in laboratory practice in the study of dust collection processes.

Known experimental installation for cleaning air from dust, containing an inertial vortex dust collector with an axial nozzle for outputting clean air and an axial nozzle for outputting dust, with first and second inlet nozzles for entering dusty air, regulating rotary valves, a feeder for supplying a dust and gas mixture, connected by an inlet to the atmosphere, and through the first pipeline with the first inlet nozzle of the dust collector, and through the second pipeline and the first regulating rotary valve with the second inlet nozzle of the dust a fan, a fan whose discharge line is connected to the atmosphere, a filter, fittings for instrumentation, while the dust outlet pipe is connected through a third pipe to a fabric filter and through a fourth pipe with a second control rotary valve with a fan suction line, and an axial outlet pipe clean air is connected to the suction line of the fan through the fifth pipe, fittings for instrumentation are installed on the first, second, third, fourth and fifth pipes gadgets (see Description of the utility model of the Russian Federation No. 13615, IPC V01D 46/02, publication 05/10/2000).

The disadvantages of this design include the inability to select dust from the inertial dust collector hopper, which does not allow an assessment of all performance parameters.

The technical problem, which this utility model is aimed at, is the possibility of studying the influence of various parameters on improving the operation of a vortex dust collector and a bag filter.

The essence of the utility model is as follows, an experimental installation for air purification from dust, containing an inertial vortex dust collector with counter-swirling flows with a cylindrical body and a conical hopper for receiving trapped dust and with its outlet pipe from the hopper, with an axial outlet pipe for clean air, with the top an inlet pipe and with a lower inlet pipe for supplying a dust-air mixture to the dust collector, while a conical bump washer is installed at the output end of the lower inlet pipe , the dust feeder is connected to the first pipe, which is connected with its output to the upper inlet pipe of the dust collector, and connected to the second pipe, inside which the first rotary damper is installed, while the second pipe is connected with its output to the lower inlet pipe for supplying the dust-air mixture to the dust collector In addition, the installation contains a series-connected axial nozzle of the dust collector, a third pipeline, a filter and a fan with inlet and outlet nozzles, the installation also contains fittings for connecting instrumentation, the cylindrical case of the dust collector is made of organic glass, the upper and lower inlets of the dust collector are tangential, a snubber swirl is installed inside the upper input of the tangential nozzle, the first retractable gate is installed on the outlet for collecting dust from the hopper, inside the first pipeline, a second rotary damper is installed, the filter is made in the form of a bag filter with a conical hopper and a cartridge the dust collection unit, on which the second sliding gate is mounted, the installation comprises serially connected axial branch pipe of the dust collector, a removable branch pipe, a third pipe, an inlet pipe of a bag filter, a bag filter, its output axial pipe, a fourth pipe, a suction pipe of the fan, the fan itself with an outlet pipe, in addition, the fittings for instrumentation are installed on the first, second and fourth pipelines.

This allows you to expand the possibilities of conducting experiments without environmental pollution to assess the efficiency of the dust collector with small dust particles, when the efficiency of the apparatus is small and the dust breakthrough is large. In addition, it is possible to study the collaboration of the dust collector and bag filter.

The essence of the utility model is illustrated by the drawing, where in Fig. 1 shows an experimental setup for dust cleaning of air, general view.

The experimental installation for cleaning air from dust contains an inertial vortex dust collector 1 with counter-swirling flows with a cylindrical body of organic glass 2, with a conical hopper 3 for receiving trapped dust and with an axial nozzle 4 for collecting dust, as well as an axial nozzle 5 for removing clean air.

The supply to the dust collector 1 of the dust-air mixture is carried out through the upper 6 and lower 7 inlet tangential nozzles, while at the output end of the lower inlet nozzle 7 a conical baffle plate 8 is installed.

On the pipe 4 output of the captured dust from the hopper 3 is installed the first retractable gate 9.

The dust feeder 10 is connected to the first pipe 11, inside which a second rotary valve 12 is installed, which is connected to the upper tangential inlet pipe 6 and to the second pipe 13, inside which the first rotary valve 14 is installed, while the second pipe 13 is connected with its output to the lower inlet pipe 7 for supplying the dust-air mixture to the dust collector 1.

The upper tangential inlet pipe 6 is provided with a snail swirl 15.

The installation comprises a bag filter 16 with a conical hopper 17 for receiving trapped dust and a pipe 18 for outputting the captured dust from the hopper 17. A second retractable gate 19 is installed on the pipe 18.

At the same time, the installation comprises axially connected pipe 5 of the dust collector 1, a removable branch 20, a third pipe 21, an inlet pipe 22 of the bag filter 16, its output pipe 23, a fourth pipe 24 at the end of which a suction pipe 25 of the fan 26 is installed, while the output pipe 27 fan 26 is connected to the atmosphere.

On the first pipeline 11, on the third pipeline 21 and on the fourth pipeline 24, fittings 28, 29, 30 and 31 are installed for connecting control and measuring devices.

The experimental setup works as follows.

Under the action of the fan 26, air from the atmosphere enters the first pipe 11, in which it is mixed with the dust supplied in the calculated amount through the feeder 10. Next, the dust-air mixture, the flow rate of which is regulated by the second rotary damper 12, enters through the pipe 11 into the upper inlet pipe 6 and the lower inlet pipe 7 through the second pipe 13 and the first re-flap 14, which regulates the flow of the dust-air mixture into the lower part of the housing 2 of the dust collector 1, as well as through the jack washer 8.

Both flows of the dust-air mixture are twisted in one direction while passing through the tangential nozzles 6 and 7. This also contributes to the twisting of the flow in the snail swirl 15.

The flows of the dust-air mixture are directed towards each other and, under the action of centrifugal and inertial forces, the dust is separated from the air and sent to the lower part of the dust collector 1 and enters the hopper 3. Through the nozzle 4 of the hopper 3, the dust is periodically unloaded using the first sliding gate 9.

The butterfly valves 12 and 14 achieve the calculated amount of dust and gas mixture supplied for cleaning.

The measurement of the flow rate of the dust-gas mixture and the degree of swirl by it before and after the vortex inertial dust collector 1 is carried out by control and measuring devices installed on the first 11 and third pipelines in the unions 28 and 29, 30, respectively.

The execution of the housing dust collector 1 made of organic glass allows you to visually observe the movement of air-field flows.

A removable outlet 20 installed between the axial pipe 5 of the outlet of the air purified in the dust collector 1 and the third pipe 21 provides the ability to provide swirling flows in the pipe 21 with various parameters.

The pipeline 21 has a length of preferably not less than 25-30 diameters of the pipeline, which allows the study to reduce the swirl of the stream along the length, with various designs of the mixed stream 20.

The air cleaned in the vortex dust collector through the axial nozzle 5, the removable outlet 20 and the third pipe 21 is sent through the inlet pipe 22 to the bag filter 16.

The bag filter 16 used in the installation allows additional purification of the air entering after cleaning in a vortex, inertial dust collector.

The dust released in the bag filter 16 settles in the conical hopper 17, from where it is discharged into the dump through the pipe 18 and the second sliding gate 19.

The air cleaned in the bag filter 16 through the axial pipe and the fourth pipe 24 enters through the suction pipe 25 and the outlet pipe 27 of the fan 26 into the atmosphere.

An additional assessment of the operation parameters of the installation is fixed by instrumentation installed in the fitting 31 on the fourth pipeline 24.

The proposed two-stage cleaning system in two stages allows us to evaluate the efficiency of dust collection in the dust collector 1 and the bag filter 16 separately, and the whole system.

Claims (1)

An experimental installation for dust air purification, containing an inertial vortex dust collector with counter-swirling flows with a cylindrical body and a conical hopper for receiving trapped dust and with its outlet port from the hopper, with an axial outlet port for clean air, with an upper inlet nozzle and with a lower inlet nozzle for supplying a dust-air mixture to the dust collector, while at the output end of the lower inlet pipe a conical baffle plate is installed, the dust feeder is connected to the first pipe a wire, which is connected by its output to the upper inlet pipe of the dust collector and connected to a second pipe, inside which the first rotary damper is installed, while the second pipe is connected by its output to the lower inlet pipe for supplying the dust-air mixture to the dust collector, in addition, the installation contains axially connected in series dust collector nozzle, third pipeline, filter and fan with inlet and outlet nozzles, the installation contains fittings for connecting a control meter devices, characterized in that the cylindrical case of the dust collector is made of organic glass, the upper and lower inlet nozzles of the dust collector body are tangential, a snubber swirl is installed inside the upper input tangential nozzle, the first retractable gate is installed on the nozzle for collecting dust from the hopper, inside the first pipe is installed second rotary damper, the filter is made in the form of a bag filter with a conical hopper and a nozzle for collecting dust, on which A second retractable gate has been installed, and the installation contains serially connected axial nozzle of the dust collector, a removable outlet, a third pipeline, an inlet pipe of a bag filter, a bag filter, its output axial pipe, a fourth pipe, a suction pipe of a fan and a fan with an output pipe, in addition, fittings for instrumentation installed on the first, third and fourth pipelines.

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