WO2018194491A1 - Industrial gas dedusting line - Google Patents

Abstract

The invention relates to environmental protection. An industrial gas dedusting line comprises baghouses, a contaminated air inlet duct which communicates with chamber-type receivers pertaining to dust-catching chambers, filter elements, and clean air chambers. The contaminated air inlet duct is provided with a common inlet manifold and is divided into branches, each of which communicates with each chamber-type receiver pertaining to the dust-catching chambers of one row of baghouses. The filter elements consist of a metal grid-like skeleton with a blind end and having a tubular fabric bag made of a filter material stretched over the skeleton. In each dust-catching chamber, filter elements are arranged in horizontal and vertical rows with their open ends opening into vertically oriented clean air chambers. Pipes with pulse tubes are mounted vertically such that the tubes are disposed opposite the open end of a corresponding filter element. A clean air outlet duct for the outlet of clean air from the clean air chambers is configured in the form of two branches which extend beneath the clean air chambers of each row of baghouses, are connected to the lower portions of the clean air chambers, and communicate with a common outlet manifold. The technical result is an increase in efficiency and reliability.

Description

 Industrial dust-gas cleaning line

 Technical field

 The invention relates to environmental protection. The invention relates to devices in the field of purification of process gases and suction air from dust and harmful gaseous components of the air. The invention can be used at the enterprises of ferrous and non-ferrous metallurgy, at the enterprises of the chemical industry, at the enterprises of the food industry and enterprises of the production of building materials, as well as at other industries where air or gas is required to be cleaned of dust. In particular, the invention contemplates the design of a cleaning line using bag filters with pulsed purging of horizontally arranged filter bags with compressed air or gas.

 State of the art

The industrial dust-gas cleaning system is known, which comprises bag filters arranged in a row, fitted with tube-shaped tube shells made of filter material and equipped with frame filter elements in the main dust-collecting chambers, with chambers located in the upper part of the main dust-collecting chambers communicating with the air duct for introducing contaminated air with the chambers of purified air air into which the open ends of the frame filter elements are removed, and with the chamber located below the main dust collectors and bunkers for collecting contaminants from the surface of the filter elements, an air duct for outputting cleaned air from the cleaned air chambers, while in the cleaned air chambers there are pipelines with impulse tubes, which are located opposite the outlet openings of the filter bags for pulsed regeneration of compressed air by these bags, said tubes through a crane and valve equipment communicated with a source of compressed air (RU 2479338, B01D46 / 02, publ. 04/20/2013). In this system, dirty gas or air is fed into the main dust collecting chamber using a dirty gas or air pipe through an inlet pipe and this flow is directed to a grid of vertically arranged frame filter elements. The flow of dirty gas or air is distributed over the volume of the main dust collection chamber and passed through textile shells, dressed on the frames of the filter elements. Clean air or gas enters the filter elements and enters the cleaned air chamber for subsequent removal through the exhaust pipe. And dust, soot, pollution elements settle on the surface of the textile shells of the frame filter elements.

 Periodically, at the time of blocking the flow of dirty gas or air, pulses produce compressed air through impulse tubes into the cavity of the frame filter elements. A feature of the known solution is that the filter elements are made with open ends. During the passage of a pulse of compressed air, a pneumatic shock occurs on the shell, which leads to its expansion and, as a result, the destruction of the accumulated pollution on the shell. Accumulated deposition on the surface of the shells is destroyed and through the gaps between the frame filter elements showered into the hopper, from where the deposition is removed.

To create a high pressure pulse of compressed air in the open with two ends of the tubular cavity, a high pressure receiver is used, from which compressed air is supplied through pipelines and valves to the impulse tubes. Since a large number of cavities of the filter elements are simultaneously processed by pulses and this processing is carried out in open cavities, then, naturally, the power of the receiver and the volume should be large. This is because in order to clean the shells of the filter elements, it is necessary to create such a pressure that would ensure the stretching of the shell or the formation of wave shifts on it. Shell deformation leads to destruction accumulated pollution on it. But according to the gas law, the gas pressure in all directions propagates identically only in a closed system, and in an open (open) system, the pressure direction shifts towards lower resistance or to the low pressure region. The frame filter element open at two ends is an open system. Therefore, when applying a pulse of compressed air, most of this flow will simply pass from one end to the other, and only a small part of the flow will create some pressure on the shell. In order for the shell deformation to be significant, it is necessary to create a very powerful impulse, which is obtained only when using large high-pressure receivers. Most of the compressed air is wasted and unproductive, wasting energy. In this regard, this solution proposes to equip the filter elements with a Venturi nozzle integrated at the inlet, which, according to the inventors, should amplify the pulse by increasing the speed of propagation of the shock wave. But in reality, this only leads to a complication of the design.

The use of containers with high pressure compressed air for industrial purposes in the form of generally accepted receivers is regulated by the order of Rostekhnadzor dated 03.25.2014 16 "On approval of the Federal norms and rules in the field of industrial safety" Industrial safety rules for hazardous production facilities that use equipment operating under overpressure "According to which installation and placement must comply with the requirements of industrial safety legislation. These requirements indicate and the need to place such receivers on separate specialized sites equipped with the necessary means to ensure safe operation.When fulfilling these requirements, the industrial cleaning system is a facility where the process of cleaning polluted air or gas is carried out, and a separate building with a receiver system. and takes up a lot of area. In the known system in the main dust collecting chamber, a scheme for the outflow of clean air through the frame filter elements into the additional cleaning chamber is used. This is due to the fact that the polluted stream coming from above from the input duct of the polluted air is directed along the filter elements. Therefore, the upper zones of these elements become more polluted than the lower ones: the quality of cleaning is reduced. The cleaning process in bag filters is based on the presence of pressure differences at the inlet to the main dust collecting chamber and at the outlet in the cleaned air chamber. And when using an additional cleaning chamber, it is necessary to create the same pressure difference between the main dust collecting chamber and the additional cleaning chamber, as well as the pressure difference between the additional cleaning chamber and the purified air chamber. Such a stepwise system for determining the difference in pressure leads to the fact that in one of the chambers there will always be insufficient pressure or in the chambers there will be insufficient pressure difference. This is because the pressure difference is formed by an exhaust fan, which is located at the outlet of the clean air duct. And between the main dust collecting chamber and the secondary camera there is no such fan. This is also the reason for insufficient cleaning in the main dust collection chamber. From the additional purification chamber, the purified stream rises upward through the duct. Thus, the developed layout scheme is used in the system, according to which all chambers and associated ducts are arranged in series. With this design, the system, as a complex, acquires large dimensions and occupies a large area, which translates the complex into a structure that requires a free surface on the territory of the industrial enterprise.

Thus, in the known system of industrial dust and gas purification, the problem with the quality of cleaning is directly related to the increased dimensions of the complex itself. And cleaning is closely related to the circuit design of bag filters. In addition, the known system does not have reservation, that is, cleaning by regeneration is possible only during a period of complete stoppage of the complex. The shutdown of the complex even requires the breakdown of one bag filter or another unit in the complex.

 Disclosure of invention

 The present invention is aimed at achieving a technical result, which consists in increasing productivity by increasing the cleaning performance of the filter elements in the main dust collecting chamber while reducing the energy consumption for cleaning and increasing the operational reliability of the line by providing redundancy.

The specified technical result is achieved by the fact that in the line of industrial dust and gas purification containing bag filters made with covered tubular shells of filter material by frame filter elements in the dust collecting chambers of each bag filter, the air duct for introducing polluted air in communication with the chamber receivers of dust collecting chambers in which the frame filter elements located above the bunkers for receiving sedimented contaminants, open ends brought into the chambers of cleaned air, which are in communication with the cleaned air outlet duct, while in the cleaned air chambers there are pipelines with impulse tubes, which are located opposite the outlet openings of the filter bags for pulsed regeneration by compressed air of these bags, while these pipes are in communication with the source of compressed air through a tap and valve apparatus air, bag filters are installed in at least two linearly arranged rows, the air duct for the input of polluted air is made with a common inlet pipe is divided into branches, each of which communicates with each receiver chamber dust collecting chambers of one row of bag filters, each bag filter, each filter element consists of a metallic lattice frame with anechoic one end face and stretched on this frame the tubular fabric casings filter material, in each vertically oriented main dust collecting chamber of the bag filter, the frame filter elements are arranged horizontally in rows horizontally and vertically with their open ends leading into the cleaned air chambers vertically oriented along the main dust collecting chambers, in which pipelines with impulse tubes are mounted vertically with each the impulse tube opposite the open end of the corresponding frame filter element at a distance from the open end of this filter element for supplying compressed air at a torch opening angle of 6-8 °, the cleaned air duct from the cleaned air chambers is made in the form of two sleeves that are extended under the cleaned air chambers of each row of bag filters, connected to the lower parts of the chambers purified air, and communicated with a common outlet pipe through a fan unit to create a vacuum in the chambers of the cleaned air of each row, and opposite each row of frame filter elements There is a separate pipeline with impulse tubes communicated through separate crane and valve equipment and reinforced hoses with at least one source of compressed air, made in the form of at least one plugged pipe with an internal diameter of not more than 150 mm, in communication with the compressed filling unit by air.

 These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

 Description of the figures of the drawings

 The present invention is illustrated by a specific example of execution, which, however, is not the only possible, but clearly demonstrates the possibility of achieving the desired technical result.

In FIG. 1 is a side view of an industrial dust and gas purification line; FIG. 2 is a view from the side of the fans of the ducts of purified air or gas;

 FIG. 3 is a view of a purified air or gas duct of an industrial dust and gas purification line;

 FIG. 4 is a general view of the bag filter from the side of the bag grate; FIG. 5 is a side view of a bag filter;

 FIG. 6 is a fragment of a bag filter regeneration system;

 FIG. 7 is a side view of the frame of the filter element with a partial cut-out of the shell on it;

 FIG. 8 shows a cleaning process using filter elements.

 The best embodiment of the invention

 According to the present invention, there is considered the construction of an industrial dust and gas purification line with bag filters and a filter element regeneration device, the advantage of which is a high degree of purification of polluted air or gas by horizontally arranged frame filter elements, low energy consumption for the regeneration process, and sufficient high durability during continuous operation due to the formation of redundancy, that is, the possibility of functioning upon exit and order filter bag in one of the rows.

In general, an industrial dust-gas purification line contains bag filters made with frame-covered tubular shells of filter material in the dust-collecting chambers of each bag filter, an air inlet for polluted air in communication with the chamber receivers of the dust-collecting chambers, in which frame filter elements located above bunkers for receiving sedimented contaminants, open ends are led into the chambers of purified air, which are connected to the duct and purified air. Pipelines with impulse tubes are located in the cleaned air chambers, which are located opposite the outlet openings of the filter bags for pulse regeneration of compressed air by these bags, and these pipes are connected to a source of compressed air through a crane and valve equipment.

 Bag filters are installed in at least two linearly arranged rows.

 The air duct for the input of polluted air is made with a common inlet pipe and is divided into sleeves, each of which is in communication with each chamber receiver of the dust collecting chambers of one row of bag filters.

 In each bag filter, each filter element consists of a metal grating frame with one end plugged and a fabric tubular casing made of filter material stretched onto this frame.

 In each vertically oriented main dust collecting chamber of the bag filter, the frame filter elements are arranged horizontally in rows horizontally and vertically with their open ends vertically oriented along the main dust collecting chambers of the cleaned air, in which pipelines with impulse tubes are mounted vertically with the location of each impulse tube opposite the open end of the corresponding frame filter element at a distance from the open end of the filter element for supplying compressed air at an angle equal to the torch disclosure 6-8 °.

The air outlet of the cleaned air from the cleaned air chambers is made in the form of two sleeves that are stretched under the cleaned air chambers of each row of bag filters, connected to the lower parts of the cleaned air chambers, and each is connected through a separate fan unit to create a vacuum in the cleaned air chambers of each row with common outlet pipe. Opposite each row of frame filter elements there is a separate pipeline with impulse tubes communicated through a separate crane and valve apparatus and reinforced hoses with at least one source of compressed air, made in the form of at least one plugged pipe with an internal diameter of not more than 150 mm, communicated with a node for filling it with compressed air.

 Below is an example of a specific implementation of the industrial dust and gas cleaning line.

 In general, the line is based on the use of bag filters 1 installed in a row (Figs. 1-3). At the same time, bag filters 1 are installed in at least two linear rows 2 and 3 and are mounted on a platform located at a distance from the supporting surface on the racks and are grouped in two rows 2 and 3, between which the passage is made and over which the canopy is made.

 The air duct 4 for inputting contaminated air is filled with a common inlet pipe 5 vertically oriented from one end of the platform, which is divided into two arms, each of which is in communication with a chamber 6 in communication with the main dust collecting chambers 7 of the bag filters of the first row (Fig. 1).

 An air duct 8 for outputting cleaned air from the cleaned air chambers is made in the form of two sleeves 9 and 10 (FIGS. 2 and 3), which are stretched under the cleaned air chambers 11 of each row of bag filters, connected to the lower parts of the cleaned air chambers, discharged from the other end of the platform under the platform towards the duct 4 of the input of polluted air and each communicated with two sleeves 12 and 13 with a separate fan unit 14 located on the supporting surface for each sleeve (one for each row). Through fan installations, these sleeves are communicated with the outlet pipe 15 common to all these sleeves (Fig. 3).

A feature of such a layout of the line is its high maintainability and uninterrupted operation in emergency 2018/000248 mode and regeneration mode. This is made possible by the formation of at least two independent treatment streams. If regeneration of bag filters in one stream is required, then the cleaning process in this row of bag filters can be stopped and regeneration of frame filter elements can be carried out. At the same time, the cleaning process itself does not stop, since another row of bag filters functions. The redundancy function remains high, eliminating the temporary cessation of all cleaning.

 However, such a compact architecture of the system, as a complex, was made possible thanks to the use of bag filters 1 with an increased packing density of the frame filter elements 16, horizontally placed on the path of polluted air.

 In the General case, bag filters 1 are made with fitted tubular shells 17 of filter material frame filter elements 16, which are located in the main dust collecting chambers 7, and the open ends of which are displayed in the chamber of purified air. In the chambers 11 of the cleaned air there are pipelines with impulse tubes, which are located opposite the outlet openings of the filter elements 16 for pulse regeneration of these elements by compressed air, while these tubes are in communication with a source of compressed air through a crane and valve apparatus.

The bag filter housing (Figs. 4 and 5) is divided into upper and lower sections 18 in which frame filter elements 16 are fixed, arranged horizontally in rows horizontally and vertically. In the purified air chamber 11, pipelines 19 with impulse tubes 20, which are located opposite the outlet openings of the filter elements 16 in each vertical row for pulsed regeneration of compressed air by these bags, are attached to the housing in each section opposite each other in the vertical rows of filter elements 16. A feature of this bag filter is that due to a change in the design of the frame filter elements it has become possible to increase the density of their laying in the bag grate of the main dust collecting chamber. Such filter elements as cartridges or cartridges are horizontally inserted through the technological windows in the baghouse 21 so that the larger transverse size of the cartridge element is located vertically. Thus, in the filter housing, the filter elements 16 are arranged horizontally and vertically in rows at a certain distance from each other, sufficient for the passage of contaminated air or gas flow between these elements. The density of such elements determines the cleaning efficiency of the incoming contaminated agent. Each filter element 16 is a lattice structure flattened across the cross-section of a metal frame, which is stretched textile cover with the function of filtering air or gas.

Dirty gas or air is fed into the main dust-collecting chamber 7 of the bag filter (key 21) (FIG. 8). Using the filter cloth of the casing 17, dust is filtered which is deposited on the filter cloth and the purified gas or air enters the internal cavity of the filter element, where the frame of the filter element is located. Then clean gas or air is removed (item 22) through the open end 24 of the filter element from the main dust collection chamber into the cleaned air chamber 11. After a set period of time or with an increase in aerodynamic resistance of the dirty gas or air flow, more than the set value, pulses of compressed gas or air are supplied to the filter element cavity (pos. 25) from the impulse tubes through pipelines 19 of the high impulse pressure supply system and the fabric sleeve is blown with this compressed gas or air from the open end of the filter element. There is a destruction of the dust accumulated on the fabric membrane, which is blown out. Dust particles fall down bag filter and accumulate in the lower part of the bag filter housing in a special hopper 26 (which is periodically cleaned from dust accumulation).

 To ensure high volumetric efficiency of cleaning the bag filter, the casing 17 is blind with one end to cover the end part of the metal frame and open from the other end (Fig. 7). The open end is used to discharge purified gas or air from the bag filter. Structurally, the metal frame consists of inseparably connected by welding between each other made of metal rods longitudinal 27 and transverse 28 ribs. From the side of the blind end of the fabric tubular sleeve, an end plate 29 with bent sides is attached to the frame, to which the bent ends of the metal rods of the longitudinal ribs 27 are welded. Since the fabric tubular sleeve has less strength with respect to the structure of the metal frame and is a stitched structure, applying pulsed pressure to the cavity of the filter element (to clean the surface of the fabric sleeve from accumulated dirt), a powerful air impact occurs along the sleeve, including part of it. The direction of this pneumatic shock (shock air or gas wave) is towards the muffled part of the shell, which leads to the destruction of the sleeve in this zone. To avoid this and to ensure the integrity of the fabric tubular sleeve, longitudinal ribs in the area of the blind end face of the sleeve are welded to the end plate 29, which is a shock wave limiter and a sleeve fuse. The shock wave is reflected from the plate and changes the motion vector.

 The purification of the shells in sections is carried out during the period of blocking the access of dirty air to the chamber 7 or during the period when this contaminated air or gas does not come from the industrial enterprise.

Essential in this bag filter is the cross-sectional shape of the frame (flattened) and the arrangement of the filter elements with a long transverse vertical dimension of the bag grate. Such the location allows you to accumulate pollution mainly on the lateral flat sections of the shell and on the conical protrusions. This allows not only to increase the cleaning of the dirty stream, but also to provide high cleaning of the shell when it is purged with a pulse of compressed air from the inside. Since, according to the gas law, air pressure in a closed volume is distributed in all directions equally, then with a pneumatic shock, a certain stretching of the shell occurs over its entire surface, which leads to the destruction of accumulations. And since these contaminants are located on surfaces where the solid angle is less than the adhesion force (due to the geometry of the cross section of the filter element), the contaminant particles are not retained on the shell and fall into the hopper along the same vertical corridors created between the vertical rows of filter elements .

 In the bag grate, the frame filter elements are located in the upper and lower sections 18, opposite the filter elements in each of which and for each vertical row of these elements there are separate pipelines 19 with impulse tubes 20. These impulse tubes are located at such a distance from the open ends of the filter elements for compressed air supply, so that at an angle of opening of the torch equal to 6-8 ° the issued pulse of compressed air overlaps the entire cross section of the open end of the filter element ta.

With this design, the air mass in the cavity of the filter element, not being able to exit the cavity, is compressed and forms a shock wave front that moves towards the muffled end of the frame. The presence of a front forms a closed system in the cavity of the filter element, in which the flow pressure propagates equally in all directions. A sharp increase in pressure in the cavity of the shell occurs, leading to its deformation, including the wave. This ensures the destruction of the accumulated pollution on the shell due to the fact that the shell and the layer of pollution have different expansion. Reaching the stub in the cavity of the filter element, the shock wave returns in the opposite direction towards the open end, but with less energy. During the reverse stroke, the pressure also expands on the shell, which again leads to the dumping of accumulation residues.

 Also a feature of the claimed solution is that the entire volume of the pulse in its flare zone falls into the cavity of the frame of the filter element, that is, there is no loss of air mass and, therefore, the pulse energy. This became possible when, as a result of experiments, it was found that the ends of the impulse tubes should be located at a distance of 63-68 mm from the open ends of the frame filter elements. In this case, the air mass pulse emerging from the impulse tube acquires a conical shape with a torch opening angle of 6-8 °. When taking into account the size of the inlet of the filter element, such a torch completely enters the cavity of the frame filter element without loss of pulse energy. The optimal distance is 66 mm. With the optimal choice of distance, the torch enters the cavity with guarantee. At a distance of less than 63 mm, impulse tubes fixed stationary in the purified gas chamber impede the operation of extracting filter elements from the baghouse.

It is also significant in this process that a small pressure of a compressed gas is enough to create a pulse forming a shock wave, since there is no loss of pressure of the compressed gas, which leads to a significant saving in energy consumption for creating pressure (there is no loss of pulse energy at the inlet to the filter element). In this regard, it became possible to abandon the standard high-pressure receivers and all that is associated with the requirements for their use. In the claimed invention, the receivers, as sources of compressed air, are made in the form of at least one plugged pipe 30 with an inner diameter of not more than 150 mm, in communication with the node for filling it with compressed air. Such sources are relatively security. Since the claimed solution does not need to create large containers with compressed air, for each section and / or for each vertical row of filter elements, you can use your own separate source of compressed air in the form of a plugged pipe 30 with an inner diameter of not more than 150 mm: for the upper and the lower sections of the filter elements of the vertical row a separate small-capacity receiver is used in the form of a piece of a plugged pipe. This reduces the hazard class of the bag filter and the entire process associated with it.

 Another feature of the claimed invention is that there is no need to lay long sections of pipelines connecting the pipelines 19 to the source / s of compressed air. These sources can be mounted on the upper and / or lower (bottom) wall of the purified air chamber. At the same time, the lengths of the connecting hoses and pipelines are sharply reduced, which are connected to a source of compressed air through a separate crane 31 and valve 32 equipment and reinforced hoses 33. The use of reinforced pchangs in the connection chain before compressed air is fed into the pipeline eliminates the influence of the temperature difference between the temperature of the compressed air and the ambient temperature, this allows you to save the original parameters for the temperature and pressure of the compressed air supplied through the hoses until it leaves the impulse tubes 20. Reinforced hoses have high strength and are inert to corrosion processes, including cavitation corrosion, to which the metal walls of the pipeline are exposed s due to the impact of the gases of the fluid at the time of transition of the liquid into a gaseous state.

Such a source of compressed air can be used as a common one for several pipelines 19. The pressure of compressed air from the plugged pipe 30 is supplied through, for example, a crane apparatus (valve 31 in a square distribution pipe 33, to which pipelines 19 are connected via valve apparatus 32. Industrial applicability

 The present invention is industrially applicable and can be implemented in industrial cleaning complexes. The invention improves the safety of the regeneration process. The invention improves the productivity and speed of cleaning filter elements while simplifying the design of impulse tubes and reducing energy consumption. The increase in productivity and cleaning speed is due to the fact that a complete pulse of air / gas enters the cavity of the filter elements without losing its energy. This leads to improved cleaning efficiency and reduced time for this process. The decrease in energy consumption is due to the fact that while maintaining the full energy of the pulse, there is no need to increase the pressure in this pulse, which leads to a decrease in energy consumption for the operation of equipment that creates pressure in the receivers. Using instead of Laval nozzles for impulse tubes, simple-shaped tubes of the type of bushings can seriously simplify the design of the regeneration system.

Claims

Claim An industrial dust-gas purification line containing bag filters made with framed tubular shells of filter material by frame filter elements in the dust-collecting chambers of each bag filter, an air duct for introducing polluted air in communication with the chamber receivers of the dust-collecting chambers, in which frame filter elements located above the receiving hoppers contaminants, open ends are led into the chambers of purified air, which are cleaned with the outlet duct about air, while in the chambers of cleaned air there are pipelines with impulse tubes, which are located opposite the outlet openings of the filter bags for pulse regeneration by compressed air of these bags, while these pipes are connected through a tap and valve apparatus to a source of compressed air, characterized in that filters are installed in at least two linearly arranged rows, the air inlet for polluted air is made with a common inlet pipe and is divided into sleeves, each of which It is communicated with each chamber receiver of dust collection chambers of one row of bag filters, in each bag filter, each filter element consists of a metal grating frame with one end plugged and a fabric tubular shell stretched over the frame made of filter material, in each vertically oriented main dust collection chamber of the bag filter filter elements are arranged horizontally in rows horizontally and vertically with the conclusion of their open ends in a vertical orientation cleaned air chambers along the main dust collecting chambers, in which pipelines with impulse tubes are mounted vertically with each impulse tube opposite the open end of the corresponding frame filter element at a distance from the open end of this filter element for supplying compressed air at an opening angle a torch equal to 6-8 °, the cleaned air outlet duct of the cleaned air chambers is made in the form of two hoses that are connected to the lower parts of the cleaned air chambers, and are each communicated through a separate fan unit to create a vacuum in the cleaned air chambers of each row with a common outlet and, opposite each row of frame filter elements, there is a separate pipeline with impulse tubes communicated through separate crane and valve equipment and reinforced hoses with at least at least one source of compressed air, made in the form of at least one plugged pipe with an inner diameter of not more than 150 mm, in communication with the site of its filling with compressed air.