RU2416455C2 - Separation system with vorject dust separator - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to gas cleaning of dust and may be used in various industrial branches. Proposed dust separator comprises cylindrical housing 1, axial dusty gas intake with swirler 4, ejector 7, spinner 5 and conical bumper washer. Housing top accommodates axial clean gas discharge branch pipe and secondary flow peripheral intake 8 with swirler 9. Said axial clean gas discharge branch pipe is communicated with air duct 10 provided with inlet branch pipe 23 of the frame sleeve filter. Filter comprises housing 17, filtration section 21 with boxes 22 and 23 for dusty gas intake and clean gas discharge, filtration sleeves 16 with frame 19, tubular grating, dust collection bin 18 and regeneration mechanism. The latter consists of solenoid valve 11, compressed air feed pipe 12, Venturi nozzle 14 and regeneration automatic control device 15. Filter comprises also temperature pickup, dust collector dust level alarm pickup, thermal automatic annunciator detector and manifold with nozzles to be connected to fire fighting system incorporating control unit arranged in filtration section outlet box, their outlet being connected to common microprocessor.

EFFECT: higher efficiency of separating low-specific weight particles and system reliability.

1 dwg

Description

The invention relates to techniques for cleaning gas from dust and can be used in various industries in pneumatic conveying systems, pneumatic cleaning, aspiration.

The closest technical solution to the claimed object is a vortex dust collector according to the patent of Russian Federation No. 2337763, B01D 45/12 dated 06/15/04, containing a cylindrical body with a conical hopper and an axial inlet pipe located in its lower part, a cowl and a bump washer located on the end surface cylinder, as well as placed in the upper part of the pipe for the input of the secondary stream and the outlet pipe connected to the filter (prototype).

The disadvantage of the prototype is the relatively low efficiency of the dust collection process.

The technical result is an increase in the efficiency of dust collection.

This is achieved by the fact that in an aspiration system with a vortex dust collector containing a two-stage gas dust cleaning system, in which the first stage of gas-air mixture purification is a vortex dust collector operating on the principle of counter-swirling flows, and the second cleaning step is a filter, the vortex dust collector contains a cylindrical axial housing the introduction of dusty gas with a swirl and an ejection nozzle, which forms an annular channel with an input wall formed by conical surfaces corresponding to the axial axis an ode and an ejection nozzle, a cowl and a conical baffle plate, as well as an axial nozzle located in the upper part of the housing for outputting purified gas and a peripheral inlet of the secondary stream with a swirl, and an air duct fixed to the inlet of the cleaned gas nozzle connected to the inlet pipe of the frame bag filter with pulsed purge containing a housing, a filter section with boxes for entering dusty and purified air, filtering sleeves with a frame, a tube sheet, a dust bin and fur regeneration unit, consisting of a solenoid valve, pipes for supplying compressed air with nozzles, Venturi nozzles, an automatic regeneration control device connected to a common microprocessor, and the filter is additionally equipped with a temperature sensor, and an dust level alarm sensor is installed in the dust collection bin in the outlet box the filter section is equipped with a thermal automatic detector detector, the outputs of which are connected to a common microprocessor, and in the output box of the filter section of the dust collector is installed to llektor with nozzles for connection to the fire extinguishing system, a control unit which is connected to a common microprocessor.

The drawing shows a diagram of an aspiration system with a CDW apparatus and a frame filter.

The suction system with a CDW apparatus and a frame filter is a two-stage gas dust removal system in which the first stage of gas-air mixture purification is a vortex dust collector operating on the principle of counter-swirling flows (CDW), and the second is a frame filter.

The vortex dust collector comprises a cylindrical housing 1 with a hopper 2, an axial inlet 3 with a swirl 4, a cowl 5, a breaker washer 6 and an ejection nozzle 7, an inlet 8 of the secondary flow with a swirl 9, an axial nozzle for removing purified gas.

The axial pipe for outputting the pre-purified gas is connected by an air duct 10 to the inlet pipe 23 of the frame filter

The frame bag filter with pulse purge contains a housing 17, a filter section 21 with boxes 22 and 23 for entering dusty and purified air, filter bags 16 with a frame 19, a tube 20, a dust collecting bin 18 and a filter regeneration mechanism consisting of a solenoid valve 11, pipe 12 for supplying compressed air, nozzle 13; Venturi nozzle 14, device 15 automatic regeneration control. The frame bag filter is equipped with a fire system (not shown) including the following elements. A temperature sensor is installed in the filter block housing, an emergency dust level sensor in the dust collection bin, a thermal automatic detector detector in the output box, the outputs of which are connected to a common microprocessor located in the control cabinet, and a collector with nozzles for connection to a fire extinguishing system, the control unit of which is connected to a common microprocessor, and the bag filter regeneration system contains a control unit that is electronically connected to a common microprocessor.

The aspiration system with a CDW apparatus and a frame filter operates as follows.

The dusty gas-contaminated stream enters through the inlet 8 and, spinning with the scapular swirler 9, moves downward in the housing 1. Primary dusty gas is supplied towards it from below through the axial inlet 3, which is swirled by the axial-scapular swirler 4 in the same direction as the descending secondary stream. In this case, dust particles are thrown to the walls of the housing under the action of centrifugal forces 1. The swirling secondary stream, encountering the baffle plate 6, partially unfolds, interacting with the primary stream coming from the central inlet 3. Dust particles with greater inertia are separated from the stream when it turning at the baffle plate 6 and through the gap between it and the walls of the housing 1 fly into the hopper 2. In the hopper 2, a vacuum is created due to the ejection nozzle 7 installed in the axial inlet 3 close to the swirl 4. Suction an ejector, a stream that can contain the smallest dust particles, especially with a small specific gravity and a size of less than 10 microns (light solid particles), enters directly onto the blades of the swirler 4, and at the maximum radius, which ensures their maximum swirling and removal from the periphery of the gas stream into the secondary stream and then back to hopper 2. This contributes to the optimal interaction of the swirling stream of the primary stream with the downward flow of the swirling secondary stream and to increase the efficiency of dust collection by returning to the hopper Dere dust particles with a low specific gravity. The installation of a filter at the outlet of the purified gas allows for high efficiency of separation of small particles with a low specific gravity and to bring the dust content of the air of the working area to sanitary standards.

The filter works as follows.

The inlet pipe 23 of the frame filter is connected by an air duct 10 to the outlet of the axial pipe to output the purified gas in a vortex dust collector.

The purified air enters the filter section 21 of the bag filter, then inside the vertically arranged filter elements 16 in the form of filter bags with a frame, and then into the duct 22 for the release of purified gas located above the filter section 21.

Under the housing 17, there is a conical hopper 18 with a double flasher type dust puller (not shown) or a conical hopper with a dust bolt screw with a manual drive with a dust puller rotary shutter type valve, as well as a local auger control unit and a rotary lock shutter. A dust level sensor (not shown) is installed on the hopper.

The filter housing is equipped with a support rack (not shown in the drawing), made in the form of at least three posts rigidly interconnected by horizontal rods, and inclined stiffeners, one end of which is connected to the racks and rods, and the other to the hopper 18 filter. On the viaduct, stairs and railings are rigidly installed and fixed between themselves and the filter housing 17.

As a material for filter elements of a bag filter, the following can be applied: non-woven polyester reinforced with an internal frame mesh; non-woven aramid hardened by an internal wire mesh; non-woven thin-fiber polyester, reinforced with an internal wire mesh, with a special coating; moisture resistant non-woven polyester, hardened with an internal frame mesh, with a special coating; non-woven, hardened with an internal frame mesh polyester, antistatic with oil and water repellent impregnation with a smooth surface; non-woven, thin-fiber polyester, reinforced with an internal wire mesh, with a special coating. The fine-fiber composition of the filter element allows you to get very low rates of residual dust - not more than 0.2 mg / m ³ .

Filter regeneration. The excess pressure of compressed air during regeneration is 0.4 ... 0.8 Pa; the pulse duration is 0.1 ... 0.2 s. The pulse frequency depends on the nature of the change in filter resistance. In this method, mechanical shaking, which ensures deformation of the fabric and the destruction of the dust layer, is combined with backflushing. The Venturi nozzle installed at the inlet to the sleeve contributes to the effect of the reverse purge, since there is an additional ejection of purified gases into the sleeve. Usually at the same time 5 ... 10% of bags are blown without stopping the filtering process. The length of the sleeves does not exceed 2.5 ... 3.5 m; control of electromagnetic valves of compressed air is automated. In such filters, the gas load is usually 2 ... 4 times higher than in filters with shaking and is 1.5 ... 6 m / min.

To optimize the dust collection process and to operate it safely, a temperature sensor (not shown) is installed in the filter housing, an emergency dust level sensor is in the dust collection bin, and an automatic thermal detector is located in the output box 22, the outputs of which are connected to a common microprocessor located in the control cabinet, and in the output box there is a collector with nozzles for connecting to a fire extinguishing system, the control unit of which is connected to a common microprocessor, and the bag filter regeneration system contains bl to the control that is associated with a common electronic communication microprocessor.

A thermal detector detector and a collector with nozzles of the fire extinguishing system are installed in the output box 22 of the filter because it is the output link in the proposed device, and in order to prevent the spread of flame in case of fire further through the ventilation ducts, these systems are installed here, which will increase reliability and security of the entire device. The work of the collector with nozzles is carried out according to the principle of opening the emergency solenoid valve for water supply, when a control signal is supplied to the valve from a common microprocessor, which processes the signal from the heat detector detector, which in turn responds to an increase in temperature in the outlet box, up to self-ignition of dust aerosols and filter media filter unit.

The operation of the powder fire extinguishing system (not shown) occurs in a duplicate version, if, for example, the water supply solenoid valve fails or the water supply system is disconnected, then the powder fire extinguishing system will work, and the operation of these systems will be controlled by microprocessor, which can be placed stationary (for example, in the control cabinet) or be built into a remote control (not shown), so that in case of an accident it is possible to control the fire extinguishing process I am stopping at the same time the spread of fire, which in general will increase the security of the entire air purification system from dust.

Dust collectors of this type are designed for central aspiration systems. Pulse regeneration filters are widely used in technological processes with low and high gas performance at ordinary and high temperatures. In the apparatus there is a decrease in vibro-acoustic energy, since the filter elements are simultaneously an aerodynamic silencer of active (sorption) type noise.

Claims (1)

A suction system with a vortex dust collector, containing a two-stage gas dust removal system, in which the first stage of gas-air mixture purification is a vortex dust collector operating on the principle of counter-swirling flows, and the second cleaning step is a filter, the vortex dust collector contains a cylindrical body, the axial introduction of dusty gas and swirls an ejection nozzle, which forms an annular channel formed by the conical surfaces of the axial input and the ejector nozzle, respectively, with the input wall , a cowl and a conical baffle plate, as well as an axial nozzle located in the upper part of the housing for outputting purified gas and a peripheral inlet of the secondary stream with a swirl, characterized in that an air duct is fixed at the end of the axial nozzle of the purified gas connected to the inlet of the frame filter bag with a pulse a purge containing a housing, a filter section with boxes for entering dusty and purified air, filtering sleeves with a frame, a tube sheet, a dust collection bin and a mechanism of regeneration, consisting of a solenoid valve, a pipe for supplying compressed air with nozzles, Venturi nozzles, an automatic regeneration control device connected to a common microprocessor, and the filter is additionally equipped with a temperature sensor, and an dust level emergency sensor is installed in the dust collection bin in the outlet box the filter section is equipped with a thermal automatic detector detector, the outputs of which are connected to a common microprocessor, and in the output box of the filter section of the dust collector is installed Héctor with nozzles for connection to the fire extinguishing system, a control unit which is connected to a common microprocessor.