RU2660851C1 - Fire-protection complex for dust collection systems - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: invention relates to a dust collection technique. Fire and explosion safety system for a dust collection system comprising a housing, a support part with a dust collecting bin, inlet and outlet ducts of the filter section of the dust collector, a temperature sensor installed in the housing of the filter section, an emergency dust level sensor – in the dust collector bin, a thermal automatic detector – in the outlet duct of the filter section, the outputs of which are connected to a common microprocessor located in the control cabinet. In the output duct of the filter section, a collector with atomizers for the fire and explosion safety of the device with the control unit and a system for regenerating bag filters with a pulse blowing mechanism, which is provided with a control unit for each solenoid valve of the nozzles and is connected to a common regeneration control unit, electronically coupled to a common microprocessor, are installed. Each of the nozzles comprises a body and, coaxially disposed, and rigidly connected thereto in the upper part, a fitting with an inlet cylindrical bore connected to a diffuser, which is axially symmetric in the housing, on which a perforated disk is disposed. In the lower part of the housing a nozzle with at least three projections centering it in an axial cylindrical chamber is located axisymmetric to the body. Nozzle is made with a central hole, on the inner surface of which a screw thread is made, and a hollow helical conical swirler is placed between the perforated disk and the nozzle. Nozzle is pressed against the atomizer body by a threaded washer with a central confuser.

EFFECT: complex provides an increase in the efficiency and reliability of the dust collection process.

1 cl, 3 dwg

Description

The invention relates to techniques for fire and explosion safety for dust collection systems and can be used in chemical, textile, food, light and other industries for cleaning dusty gases, and is intended for central aspiration systems.

The closest technical solution to the claimed object is the dust collection unit according to the patent of the Russian Federation No. 2308318, comprising a housing, a support part with a dust collection hopper and a dust collecting trolley or a lock reloader, an inlet and outlet box of the filter section of the dust collector with bag type filters, a filter regeneration mechanism, this in the inlet box of the filter section is installed gas distribution device, made in the form of a wing plate with a mechanism for changing its width and a control unit, and The corrugated plate consists of two flaps, tightly adjacent to each other so that they form a plate that performs the functions of an inertial dust separation element, and a temperature sensor is installed in the filter section housing, an emergency dust level sensor is in the dust collection bin, and in the filter outlet box sections - thermal automatic detector detector, the outputs of which are connected to a common microprocessor located in the control cabinet, and a collector with suckers of the fire extinguishing system with a control unit connected by electronic communication with a common microprocessor, and a bag filter regeneration system with a pulse purge mechanism, which is equipped with a control unit for each nozzle solenoid valve and connected to a common regeneration control unit connected by electronic communication with a common microprocessor (prototype) .

The disadvantage of the prototype is the relatively low efficiency of fire and explosion safety of the device due to the relatively low degree of atomization of the extinguishing agent nozzles.

The technical result is an increase in the efficiency of fire and explosion safety.

This is achieved by the fact that in the fire and explosion safety complex for dust collection systems containing a housing, a support part with a dust bin, an inlet and outlet duct of the filter section of the dust collector, a temperature sensor is installed in the filter section housing, and an emergency dust level sensor is installed in the dust bin, in the outlet box of the filter section - a thermal automatic detector detector, the outputs of which are connected to a common microprocessor located in the control cabinet, and in the outlet box of the filter A collector with nozzles for the fire and explosion safety system of the device with a control unit connected by electronic communication with a common microprocessor and a bag filter regeneration system with a pulse purge mechanism, which is equipped with a control unit for each nozzle solenoid valve and connected to a common regeneration control unit connected by electronic communication, are installed with a common microprocessor, each of the nozzles of the fire and explosion safety system of the device contains housing and coaxially located, and rigidly connected with it in the upper part, the fitting with an inlet cylindrical hole connected to the diffuser, made axisymmetrically in the housing, on the slice of which is perforated disk, and in the lower part of the housing, the nozzle with at least three protrusions centering it in the axial cylindrical chamber, while the nozzle is made with a Central hole, on the inner surface of which is made a screw thread, and between the perforated disk and the nozzle Situated hollow helical swirler with a conical screw thread, wherein the nozzle housing is urged toward the nozzle washer with a central threaded confuser.

In FIG. 1 shows a general view of the dust collecting device; FIG. 2 is a functional diagram of a system for providing fire and explosion safety of a device; FIG. 3 is a diagram of a nozzle of a fire and explosion safety system.

The fire and explosion safety complex for dust collection systems comprises a housing 2 of a frame design dust collection system with fences 4, a support part 1 with a dust collecting bin 13 and a dust collecting trolley 14 or a lock reloader (not shown in the drawing), as well as input 6 and output 7 of the filter section 3 a dust collector with filters 5 bag type, respectively, with inlet and outlet nozzles, and with nozzles 15 connected to the regeneration unit 19 of the filter. In the inlet box 6 of the filter section 3, a gas distribution device 8 is installed, made in the form of a leaf plate with a mechanism for changing its width (not shown in the drawing) and a control unit 9. The leaf plate consists of two wings (not shown in the drawing), tightly adjacent to each other to a friend in such a way that they form precisely a wing plate (a single, practically without gaps), which performs the functions of an inertial dust separation element. The width of the wing plate depends on the concentration of dust entering the inlet box 6 of the filter section 3, which is automatically adjusted by the mechanism for changing its width. In the case of the filter section 3, a temperature sensor 11 is installed, in the hopper 13 for collecting dust - an emergency sensor 12 of the dust level, in the output box of the filter section is a thermal automatic sensor detector 24, the outputs of which are connected to a common microprocessor 10 located in the control cabinet 25 (Fig. 2), In the outlet box 7 of the filter section 3, there are installed: a collector 21 with nozzles 23 of the fire extinguishing system with a control unit 20 connected electronically to a common microprocessor 10. The bag filter system 16 from the fur regeneration The pulsed purge system is equipped with a control unit 18 of each solenoid valve of the nozzles 22 and is connected by collectors 17 to a common regeneration control unit 19, which is electronically coupled to a common microprocessor 10.

The fire and explosion safety system for dust collection systems works as follows.

The dusty gas stream is cleaned by supplying it to the inlet box 6 of the filter section 3 of the dust collector with bag type filters 5, comprising a housing 2, a support part 1 with a dust collecting bin 13 and a dust collecting trolley 14. The gas stream is supplied through the inlet box 6, where a gas distribution device 8 is installed, made in the form of a wing plate that performs the function of an inertial dust separation element. The width of the wing plate depends on the concentration of dust entering the inlet box 6 of the filter section 3, which is automatically adjusted by the mechanism for changing its width. This allows you to evenly distribute the input stream over the entire area of the bag filters 5, having previously cleaned it by inertial deposition with a minimum hydraulic resistance for the dust stream with a given dust concentration in it. Then, through the outer surfaces of the bag filters 5, the gas enters the inner cavity of the bag filters, being freed from dust particles and enters through the outlet nozzles 15 of the bag filters 5 into the cavity of the outlet box 7 of the filter section 3. The inertial dust separation element 8 contains a mechanism 9 for changing its width and a control unit, which is electronically coupled to a common microprocessor 10. Changing the width of the plate 8 is carried out depending on the dust content and speed of the inlet gas stream. In order to optimize the dust collection process and for its safe operation, a temperature sensor 11 is installed in the filter section housing, an emergency dust level sensor 12 is installed in the dust collection bin, a thermal automatic detector-detector 24 is located in the output section of the filter section, the outputs of which are also connected to a common microprocessor 10. In the outlet box 7 of the filter section of the dust collector, a collector with nozzles is installed for connection to a fire extinguishing system, the control unit of which is connected to a common microprocessor, and rehydrating and baghouse system regeneration with pulsed purging mechanism control unit which is also associated with a common electronic communications microprocessor.

A heat detector-detector 24 and a collector 21 with nozzles 23 of the fire extinguishing system are installed in the output box 7 of the filter section because it is the output link in the proposed device, and to prevent the spread of flame in case of fire further along the ventilation ducts, we install these systems here, which will increase the reliability and safety of the entire complex containing this device.

The collector 21 operates with nozzles 23 according to the principle of opening the emergency electromagnetic water supply valve when a control signal is supplied to the valve from a common microprocessor 10. It processes the signal from a heat detector 24, which in turn responds to an increase in temperature in the outlet box, up to self-ignition of dust aerosols and filter materials.

In FIG. 3 shows a diagram of a vortex nozzle of a system for ensuring fire and explosion safety of a device.

The vortex nozzle (Fig. 3) includes a housing 26, which is made in the nozzle with a helical conical swirl consists of a housing 26 and coaxially located, and rigidly connected with it in the upper part, the fitting 27 with an inlet cylindrical hole 29 connected to a diffuser 30, made axisymmetrically in the housing 16, on the slice of which is placed a perforated disk 28.

In the lower part of the casing, there is located, axisymmetrically to the casing 26, a nozzle 34 with at least three protrusions 35 centering it in the axial cylindrical chamber 31. The nozzle 34 is made with a central hole, on the inner surface of which there is a screw thread 36. Between the perforated disk 28 and the nozzle 34 hosts a hollow helical conical swirl 32 with screw thread 33. The nozzle 34 is pressed against the nozzle body 26 by a threaded washer 37 with a central confuser 38.

The nozzle with a helical conical swirl operates as follows.

The fluid enters the housing 26 through the fluid supply channel 29 in the nozzle 27, and then through the perforated disk 28 enters the axial cylindrical chamber 31, in which it begins to twist in the hollow helical conical swirl 32 with screw thread 33.

The fluid simultaneously moves in the axial direction through the axial channels formed by the protrusions 35 of the nozzle 34, and, made therein, a Central hole, on the inner surface of which there is a screw thread 36.

In the mixing chamber, which serves as the central confuser 38, these flows interact with their additional turbulization and crushing with the formation of a finely dispersed phase. Such a fluid flow at the outlet of the central confuser 38 in the threaded washer 37 is well revealed due to centrifugal forces arising from the rotation of the fluid, and is finely dispersed inside the cone-shaped plume due to the turbulent vortex fluid flow from the nozzle.

The operation of the powder fire extinguishing system 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 10, which can be placed permanently (for example, in a control cabinet 25) or be built into a remote control (not shown in the drawing), so that in case of an accident it is possible to control the fire extinguishing process while stopping the spread of fire, which as a whole will increase the safety of the entire dust cleaning air system.

The hydraulic resistance of the filter section is 15 ... 25% of the hydraulic resistance of the entire device, which is caused by the installation of a leaf plate 8 in the inlet duct 6 with a mechanism for changing its width, which performs the functions of an inertial dust separation element of the first gas purification stage from dust. The bag-type filter material has improved sound-absorbing properties, and the body parts and guards of the device are made of structural composite or polymeric materials, such as polyethylene, nylon, polyurethane by casting, stamping, molding, and a layer of soft vibration-damping material, for example, mastic, is applied to their surface. "VD-17", "Gerlen-D", and the ratio between the thickness of the material and the vibration damping coating is in the optimal range of values: 1 / (2.5 ... 4), and on top of this layer fixed layer sound-absorbing material, for example of the "vinipor", "akmigran" with acoustically transparent protective film of the type "poviden".

A bag filter regeneration system with bag lengths of the order of L = 2.5 ... 3.5 m with a pulse blowing mechanism provides: automated control of the compressed air solenoid valves at excess pressure of the order of P _and = 0.4 ... 0.8 Pa; pulse duration τ = 0.1 ... 0.2 s; simultaneous purging of the number of hoses without stopping the filtering process m = 5 ... 10%, moreover, when blowing hoses on both sides, their length is about L = 5 ... 6 m.

The dust collection bin is made in a conical or pyramidal shape with an angle of inclination of the walls exceeding the angle of repose of the captured dust.

In the filter section of the dust collector, the bag-type filtering elements are arranged in straight rows or in a checkerboard pattern, and the ratio of the length of the sleeve L to its diameter D is in the optimal range of values: L / D = 15 ... 40, and used as woven materials as the filter bag material with weaving methods: linen, twill, satin; with the types of fibers in the thread: staple, filament, textured; with surface treatment: smooth and brushed, and non-woven with methods of fixing fibers: needle-punched, canvas-stitched and glued, obtained by the above methods from:

- natural fibers of animal and vegetable origin (woolen, linen, cotton, silk) with the following ranges of properties: density ρ = 1320 ... 1520 kg / m ³ ; heat resistance λ = 65 ... 120 ° C; tensile strength σ = 130 ... 530 Pa; tensile elongation φ = 7 ... 40%; moisture capacity w at a temperature t = 20 ° C and humidity φ = 65% is w = 7 ... 15%; with humidity ϕ = 90 ... 95% is w = 21.9 ... 27%.

- artificial organic fibers (lavsan, nitron, nylon, chlorin, oxalon, polypropylene, polyvinyl chloride, fluoroplast, teflon, etc.) with the following ranges of properties: density ρ = 920 ... 2300 kg / m ³ ; heat resistance λ = 65 ... 270 ° C; tensile strength σ = 180 ... 860 Pa; tensile elongation φ = 14 ... 50%; moisture capacity w at a temperature t = 20 ° C and humidity ϕ = 65% is w = 0 ... 4.5%; with humidity ϕ = 90 ... 95% is w = 0 ... 8.5%; artificial inorganic fibers (for example, glass fiber) with the following ranges of properties: density ρ = 2000 ... 2540 kg / m ³ ; heat resistance λ = 240 ... 315 ° C; tensile strength σ = 1600 ... 3000 Pa; tensile elongation φ = 3 ... 4%; moisture capacity w at a temperature t = 20 ° C and humidity ϕ = 65% is w = 0 ... 0.3%; with humidity ϕ = 90 ... 95% is w = 0 ... 0.5%.

Claims (1)

Fire and explosion safety complex for dust collection systems, comprising a housing, a support part with a dust collection bin and a dust collecting trolley, an inlet and outlet box of the filter section of the dust collector with bag filters, a filter regeneration mechanism, a gas distribution device is installed in the inlet box of the filter section, and a filter section in the filter section housing a temperature sensor is installed, in the dust collection bin - an emergency dust level sensor, in the outlet box of the filter section - heat automatically a detector detector, the outputs of which are connected to a common microprocessor located in the control cabinet, and in the output box of the filter section there is a collector with nozzles for the fire and explosion safety system of the device with a control unit connected electronically to a common microprocessor, each of the nozzles of the fire and explosion safety system the operation of the device comprises a housing and, coaxially located, rigidly connected with it in the upper part, a fitting with an inlet cylindrical hole, is connected with a diffuser made axisymmetrically in the body, on the cut of which a perforated disk is placed, characterized in that the nozzle with at least three protrusions centering it in the axial cylindrical chamber is located, axisymmetrically to the body, the nozzle is made with a central a hole, on the inner surface of which a screw thread is made, and a hollow screw conical swirl with screw thread is placed between the perforated disk and the nozzle, while the nozzle is pressed against the body nozzles threaded washer with central confuser.

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