CN111905554B - Dedusting and demisting desulfurizing tower - Google Patents

Abstract

The invention relates to a dedusting and demisting desulfurizing tower, which comprises a desulfurizing section (81), a demisting section (83) and an exhaust chimney (84) which are sequentially communicated; the demisting section (83) is provided with a tube bundle type dedusting demister and a baffle demister (9), the baffle demister (9) is arranged above the tube bundle type dedusting demister, and the interval between the baffle demister (9) and the tube bundle type dedusting demister is 1-1.8 m. The invention can be modified by utilizing the existing wet desulfurization tower, and has the advantages of small investment and high construction speed; the upper and lower fixing plate structures are adjusted, so that the stability of the tube bundle type dust-removing demister is enhanced, and the tube bundle type dust-removing demister is convenient to construct, overhaul and maintain; through reforming transform desulfurizing tower baffle isotructure, can eliminate the liquid film that the tube bank dust removal defogging in-process was caught and form secondary and carry, eliminate gypsum rain, realize the ultralow emission of flue gas.

Description

Dedusting and demisting desulfurizing tower

Technical Field

The invention belongs to the technical field of flue gas treatment, and particularly relates to a boiler flue gas dedusting and demisting desulfurization tower.

Background

When the wet desulfurization is adopted for boiler flue gas, a large amount of gypsum rain is generated, and the national ultra-low emission requirement is difficult to reach through a ridge demister. The tube bundle type dust and mist remover can lead the desulfurization flue gas to generate centrifugal motion when passing through the cyclone, and fine fog drops and dust particles in high-speed air flow are separated from the air under the action of centrifugal force and flow down along the inner wall of the mist removing cylinder so as to realize gas dust and mist removal, thus being widely applied.

The existing tube bundle type dedusting demister is improved by utilizing the existing desulfurizing tower, when the original ridge demister is dismantled, in order to furthest utilize the space of the original ridge demister, a hexagonal plate is generally adopted as a fixing plate of a demisting cylinder (see figure 1), but the area of the hexagonal plate can be furthest utilized due to the fact that the hexagonal plate is opened and abutted to the tube bundle cylinder, the cylinder is arranged too densely as a result, the tube bundle type dedusting demister is installed in a narrow tower body, gaps among the lower fixing plates are too small due to connection, construction is inconvenient, and sealing between the lower fixing plates is poor. When the demister works, under the impact of high-speed air flow, the fixing plates are loosened, gypsum fog drops enter the demister to form siltation, so that the inside of the tower body is polluted. Cleaning is very cumbersome. When the existing desulfurizing tower is used for transformation, the supporting beams of the original ridge demister are wider in distance and distributed in parallel strips, and the special shape of the hexagonal plates is that the stability of the demister is affected by overhead edges and uneven stress of part of the hexagonal plates when the hexagonal plates are connected into sheets is prevented, and the supporting beams are usually required to be added to ensure that the hexagonal plates after the tube bundle cylinder body is installed are stable.

In addition, the blade number and the inclination angle of the cyclone are fixed in the existing tube bundle dust removal demisting cylinder (see figure 2), when the multi-layer cyclone is arranged for demisting, the dust and fog content in the lower air flow are high, the separated fog drops are thick and large, the fog drops in the upper air flow are thin and small, the problem that the trapped liquid drops are secondarily entrained by the air flow easily occurs in the ascending process of the air flow due to the fact that the separated fog drops are thick and large, and the separation effect is poor. In addition, in the upward process of the air flow, pressure drop is generated, so that the upward air flow is decelerated, and the gas-liquid centrifugal separation effect is also affected. The existing converging flow guiding device is of a through double-funnel structure (see fig. 2) with symmetrical design, the upper funnel and the lower funnel are of equal volume design, the diameter of the middle connecting part is reduced to be a speed increaser, when the flow guiding device is used, the lower part is a converging ring, the upper part is a flow guiding ring, and the flow guiding ring is in direct contact with the end face of the converging ring to form the speed increaser. When high-speed air flow passes through, the problems that the thickness of a liquid film is difficult to control by the converging ring and the trapped liquid drops are secondarily entrained by the guide ring occur, so that the effect of the dust removal demister is affected.

Therefore, the system optimization and design are carried out on the existing desulfurizing tower, and the method has very important significance for ensuring the normal operation of the wet scrubbing flue gas desulfurization system and realizing ultra-low emission.

Disclosure of Invention

The invention aims to overcome the defects and shortcomings of the prior art, and provides a dedusting and demisting desulfurizing tower which can realize ultralow emission by desulfurizing flue gas.

In order to achieve the above purpose, the invention provides a dedusting and demisting desulfurizing tower, which comprises a desulfurizing section, a demisting section and an exhaust chimney which are sequentially communicated; the demisting section is provided with a tube bundle type dedusting demister and a baffle plate demister, and the baffle plate demister is arranged above the tube bundle type dedusting demister.

According to one aspect of the invention, the demisting section is also provided with a flushing water system which comprises a water supply pipe, a flushing water pipeline and a spray head which are sequentially connected, wherein the spray head is used for flushing the tube bundle type dust removal demister and the baffle demister through the water spray head, the upper spray head and the lower spray head respectively; the distance between the two adjacent water spray heads, the distance between the upper spray heads and the distance between the lower spray heads are 30-50 cm, preferably 40cm.

According to one aspect of the present invention, the wash water pipe includes a one-way wash water pipe installed 300-400 mm above the baffle mist eliminator, and a two-way wash water pipe installed between the baffle mist eliminator and the tube bundle dust removal mist eliminator.

According to one aspect of the invention, the bi-directional flushing water pipe is 500-700mm, preferably 600mm, from the tube bundle dust and mist eliminator.

According to one aspect of the invention, the dust and mist removal desulfurizing tower gradually reduces the inner diameter of the desulfurizing tower along the ascending direction of the airflow.

According to one aspect of the invention, a desulfurization absorption layer is arranged in the desulfurization section, the desulfurization absorption layer is a distributed calcium oxide spray system, and the sprayed calcium oxide absorbs sulfides in flue gas; preferably, the upper layer, the middle layer and the lower layer of the desulfurization absorption layer are sprayed with the absorption liquid through 3 layers of absorption liquid spray heads arranged in the desulfurization section.

According to one aspect of the invention, a gas distribution plate is further arranged 1.5-2.5 m below the desulfurization absorbing layer, preferably 2m below; the gas distribution plate is uniformly provided with a plurality of gas flow holes with diameters of 2-5 cm.

According to one aspect of the invention, the upper side and the lower side of the gas distribution plate are separated into a plurality of well-shaped gas flow channels by a plurality of gas baffles and gas flow separators which are connected in a crisscross manner, and the length, the width and the height of the gas flow channels are respectively 20-40 cm, 20-40 cm and 10-20 cm.

According to one aspect of the invention, two pairs of baffle through holes are symmetrically arranged on the upper side and the lower side of the gas distribution plate at intervals of 20-40 cm respectively, the gas flow baffle is an I-shaped baffle, two pairs of baffle through holes are symmetrically arranged on end plates on two sides of the baffle, the baffle through holes on the upper side and the lower side of the gas distribution plate correspond to the baffle through holes, and the gas baffle and the gas flow baffle are fixedly connected through bolts and nuts.

According to one aspect of the invention, a flue gas inlet is arranged at the lower part of the desulfurization section of the desulfurization tower, a transition section with a trapezoid longitudinal section is also arranged between the flue gas inlet of the desulfurization section of the desulfurization tower and the gas distribution plate, and the height of the transition section is 100-200 cm; the gas distribution plate was mounted 2.5 meters above the transition section.

According to one aspect of the invention, the lower edge of the baffle plate demister is of an arc-shaped structure which protrudes downwards and extends, and the arc-shaped structure is arranged in the center of the lower edge of the baffle plate or at intervals of 40-50 cm.

According to one aspect of the invention, the arc-shaped structure part is connected with a groove-shaped flow guide rod, the groove-shaped flow guide rod extends downwards to be connected with the lower tube bundle type dust and mist eliminator, and the flow guide rod is made of PP material.

According to one aspect of the invention, the upper end of the guide rod is connected with the arc-shaped structure of the lower edge of the baffle plate through a buckle, the upper vent hole part of the lower end, which is close to the upper fixing plate of the tube bundle type dust and mist eliminator, is fixedly connected through a connecting piece, and the lower end of the guide rod extends downwards to the inner wall of the tube bundle type dust and mist eliminator.

According to one aspect of the invention, the guide rod is a circular arc groove with a smooth surface.

According to one aspect of the invention, the space between the baffle demister and the tube bundle dust removal demister is 1-1.8 m.

According to one aspect of the invention, the tube bundle dust and mist eliminator is arranged on a supporting beam in a desulfurization section of the desulfurization tower and comprises an upper fixing plate, a tube bundle mist eliminator and a lower fixing plate which are sequentially connected.

According to one aspect of the invention, the tube bundle defogging cylinder is fixed on the supporting beam through the lower fixing plate, the supporting beam horizontally spans on the inner wall of the desulfurizing tower, and the plurality of tube bundle defogging cylinders are connected in parallel through the upper fixing plate and the lower fixing plate; a circular upper vent hole and a circular lower vent hole are respectively and penetratingly arranged in an annular ring formed at the connecting part of the tube bundle demisting cylinder and the upper fixing plate and the lower fixing plate; the upper fixing plate and the lower fixing plate are square plates with side length larger than the outer diameter of the tube bundle demisting cylinder.

According to one aspect of the present invention, the upper vent hole and the lower vent hole are opened at the center of the upper fixing plate and the lower fixing plate; and four corners of the upper fixing plate are symmetrically provided with internal threaded holes with the diameter of 1-2 cm.

According to one aspect of the invention, the tube bundle dust-removing demister further comprises a connecting sheet, the connecting sheet covers the corner of the upper fixing plate, a through hole close to the inner diameter of the corner hole is formed in the position, corresponding to the corner hole in the upper fixing plate, of the connecting sheet, and the two adjacent upper fixing plates are fixedly connected at the corner through bolts and the connecting sheet.

According to one aspect of the invention, the connection parts between the adjacent upper fixing plates, between the adjacent lower fixing plates and between the lower fixing plates and the tube bundle cylinder are sealed by sealant or plastic welding.

According to one aspect of the invention, a gap between the tube bundle dust removal demister and the inner wall of the desulfurizing tower body is sealed between the tube bundle demister cylinder and the inner wall of the desulfurizing tower body through a first blind plate and a second blind plate.

According to one aspect of the invention, the second blind plate is fixedly connected with the adjacent upper fixing plate through bolts and connecting sheets.

According to one aspect of the invention, the upper vent hole diameter is smaller than the opening size of the tube bundle demister cylinder, preferably the upper vent hole diameter is 1-4 cm smaller than the opening diameter of the tube bundle demister cylinder.

According to one aspect of the invention, the lower vent hole is sized to be the same size as or close to the tube bundle barrel inner diameter.

According to one aspect of the invention, the vertical distance between the uppermost cyclone in the tube bundle demister cylinder and the upper fixing plate is 30-50 cm.

According to one aspect of the invention, the number of the supporting beams is 8-10.

According to one aspect of the invention, the side length of the lower fixing plate is 30-60 cm, and two opposite sides are erected on two adjacent supporting beams.

According to one aspect of the invention, at least one reinforcing rib for connecting the lower fixing plate and the outer wall of the tube bundle demister tube is arranged on the upper surface of the lower fixing plate, preferably the reinforcing rib is triangular, and the reinforcing rib is welded on the lower fixing plate and the tube bundle tube outer wall through plastics.

According to one aspect of the present invention, 4 reinforcing ribs are symmetrically arranged at four corners of the lower fixing plate.

According to one aspect of the invention, at least two cross beams are pressed on the upper fixing plate to fix the tube bundle dust and mist eliminator.

According to one aspect of the invention, a demisting flushing water system is arranged above the tube bundle demisting cylinder and comprises a water supply pipe, a flushing water pipeline and water spray heads, wherein the water spray heads are downwards arranged on the flushing water pipeline at intervals, and the distance between two adjacent water spray heads is 30-50 cm, preferably 40cm.

According to one aspect of the invention, a flue gas pressure monitoring device is arranged above and/or below the tube bundle type dust and mist eliminator, and when the monitored pressure value exceeds a preset range, the water spray head is started to wash the tube bundle type dust and mist eliminator.

According to one aspect of the invention, the tube bundle demister is a multi-stage cyclone tube bundle demister and comprises a tube bundle cylinder body, a converging flow guide device and at least two stages of cyclones;

The tube bundle cylinder body is a hollow cylinder with two open ends, and the primary cyclone, the converging flow guide device and the secondary cyclone are coaxially arranged in the tube bundle cylinder body from bottom to top at intervals in sequence;

The primary cyclone and the secondary cyclone both comprise a central shaft, blades and a cyclone sleeve ring;

the blades are annularly arranged around the central shaft and obliquely arranged on the central shaft, and the cyclone lantern ring is fixed with the central shaft through the blades and is coaxially connected with the central shaft;

The blades are of a propeller type inclined blade structure, and an inclination angle is formed between the plane where the blades are positioned and the central axis to be an acute angle; the inclination angle between the plane of the primary cyclone blade and the central axis is smaller than the inclination angle between the plane of the secondary cyclone blade and the central axis.

According to one aspect of the invention, a third-stage cyclone is further arranged in the tube bundle cylinder, the third-stage cyclone is arranged above the second-stage cyclone, and a converging flow guiding device is further arranged between the third-stage cyclone and the second-stage cyclone.

According to one aspect of the invention, the blade pitch angle is 20-40 °.

According to one aspect of the invention, the blade pitch angles of the primary, secondary and tertiary cyclones are 25 °, 28 ° and 30 °, respectively.

According to one aspect of the invention, the number of blades of the cyclone increases in sequence in the direction of the air flow.

According to one aspect of the invention, the blades of the primary, secondary and tertiary cyclones are 15, 18 and 20 respectively.

According to one aspect of the invention, the blades, central shaft and swirl collar of the primary, secondary and tertiary cyclones are of integrally formed construction.

According to one aspect of the invention, the blades of the first, second and third-stage cyclones and the central shaft are integrally formed, the cyclone sleeve ring is sleeved and fixed on the periphery of the blades, and the contact part of the end parts of the blades and the inner wall of the cyclone sleeve ring is fixed through glue or welding.

According to one aspect of the invention, the cyclone is fixedly connected with the tube bundle cylinder by bolts.

According to one aspect of the invention, 3-4 internal threaded holes are drilled at opposite positions on the cyclone and the tube bundle cylinder body and fixedly connected through bolts, and preferably, the internal threaded holes are symmetrically and equally spaced relative to the central axis on the cyclone and the tube bundle cylinder body.

According to one aspect of the invention, the tube bundle cylinder comprises an upper cylinder, a lower cylinder and a docking ring which are coaxially arranged, wherein the upper cylinder and the lower cylinder are nested in the docking ring, the upper cylinder and the lower cylinder are in sealing connection through cylinder contact end surfaces, and the contact parts of the upper cylinder, the lower cylinder and the docking ring are sealed through sealing elements, preferably through plastic welding.

According to one aspect of the invention, the vanes of the primary and secondary cyclones are connected to the central shaft by right-hand and/or left-hand rotation.

According to one aspect of the invention, the vanes of the primary, secondary and tertiary cyclones are connected to the central shaft by right-hand and/or left-hand rotation.

According to one aspect of the invention, the blades of the primary cyclone are connected with the central shaft through a right-hand mode, and the blades of the secondary cyclone are connected with the central shaft through a left-hand mode.

According to one aspect of the invention, the blades of the primary and secondary cyclones are connected to the central shaft by right-hand rotation and the blades of the tertiary cyclones are connected to the central shaft by left-hand rotation.

According to one aspect of the invention, the converging flow guide device is a hollow cylinder with two open ends, a reduced middle diameter and a smooth inner wall, and comprises a converging ring, a flow guide ring and a speed increaser.

According to one aspect of the invention, the speed increaser is a speed increaser with the height of 10-100 mm, and is positioned between the converging ring and the flow guiding ring, and the speed increaser is connected with the connecting part between the converging ring and the flow guiding ring through arc transition.

According to one aspect of the invention, the speed increasing ring is of a cylindrical structure, and the diameter of the opening of the outlet end of the speed increasing ring is equal to that of the opening of the inlet end of the speed increasing ring.

According to one aspect of the invention, the speed increasing ring is of a venturi-type cylinder structure, and the diameter of an opening at the outlet end of the speed increasing ring is smaller than that of an opening at the inlet end of the speed increasing ring.

According to one aspect of the invention, the converging ring and the guiding ring are of symmetrical funnel-shaped structures relative to the speed increasing ring.

According to one aspect of the invention, the converging ring and the guiding ring are of an asymmetric funnel-shaped structure relative to the speed increasing ring, the converging ring is higher than the guiding ring, and/or the converging ring inlet end opening diameter is larger than the guiding ring outlet end opening diameter.

According to one aspect of the invention, the diameter of the inlet end opening of the guide ring is 50% -70%, preferably 60% of the diameter of the inlet end opening of the confluence ring.

According to one aspect of the invention, the guide ring is provided with a guide groove along the inner wall from the outlet end to the inlet end, and the depth of the guide groove is 1-4 mm.

According to one aspect of the invention, the diversion trench is a strip-shaped trench with a circular arc-shaped cross section or a spiral trench consistent with the airflow rotational flow direction.

According to one aspect of the invention, 3 to 8 diversion trenches are uniformly distributed on the inner wall of the diversion ring at equal intervals.

According to one aspect of the invention, the flow guide groove extends from the flow guide ring outlet end, down through the speed increasing ring along the inner wall of the converging flow guide device, to the converging ring inlet end.

According to one aspect of the invention, the converging flow guide is mounted above the cyclone of the tube bundle barrel, preferably directly interfacing with the cyclone end face.

According to one aspect of the invention, the converging flow guide device and the tube bundle cylinder are connected through a fixing piece, preferably through a bolt connection, more preferably, 3-4 internal threaded holes are drilled on the circumference of the opposite position of the converging flow guide device and the tube bundle cylinder, and are fixedly connected through a bolt, more preferably, the internal threaded holes are symmetrically and equally spaced on the converging ring of the converging flow guide device and the tube bundle cylinder relative to the central axis of the tube bundle cylinder.

According to one aspect of the invention, the components and elements of the tube bundle type dust removal demister, the baffle demister, the flushing water system, the gas distribution plate, the gas baffle, the gas flow baffle, the flow guide rod, the tube bundle cylinder, the converging flow guide device and the cyclone are all made of corrosion-resistant materials, preferably PP.

Compared with the prior art, the invention has the following beneficial effects:

1) The invention can be modified by utilizing the existing desulfurizing tower, and has high construction speed; through the cooperative coupling defogging of the tube bundle dust removal defroster and the baffle defroster, gypsum rain can be thoroughly eliminated, and ultra-low emission is realized.

Before the flue gas enters the desulfurization section for desulfurization, the flue gas enters the gas distribution plate after being guided by the transition section with the longitudinal section being trapezoidal, and the diameter of the transition section is changed (along the diameter of the rising direction of the gas flow is reduced), the upper side and the lower side of the gas distribution plate are separated into independent well-shaped gas flow channels, so that the flue gas can be rectified and uniformly distributed, the flue gas enters the desulfurization absorption layer of the desulfurization section through the gas flow holes on the gas flow channels, the rising gas flow of the flue gas can be rectified, the uniform distribution of the flue gas is realized, the purpose of fully absorbing sulfides in the flue gas is achieved, and the desulfurization effect is improved. Through 3 layers of absorption liquid spray heads arranged in the desulfurization section, the upper layer, the middle layer and the lower layer of the desulfurization absorption layer are sprayed with absorption liquid at the same time, so that the desulfurization of flue gas can be accelerated, and the desulfurization effect is improved.

The lower edge of the baffle plate demister is designed into an arc-shaped structure protruding downwards and is connected with a groove-shaped guide rod, so that liquid drops condensed on the baffle plate can flow to the arc-shaped structure along the lower edge of the baffle plate and flow to the inner wall of the lower tube bundle demisting cylinder body along the groove of the guide rod to the desulfurization section, the probability of secondary fog drop entrainment of the baffle plate demister is reduced, gypsum rain can be thoroughly eliminated, and ultra-low standard discharge of flue gas is ensured.

2) The tube bundle demisting cylinder has the advantages of good stability, convenience in installation and convenience in maintenance. The upper fixing plate is utilized to naturally form the water blocking ring, so that the structure is simple, the construction is convenient, and a liquid film formed on the inner wall of the cylinder is prevented from being carried out by gas to form secondary entrainment; the vertical distance between the cyclone at the uppermost layer of the tube bundle demisting tube and the upper fixing plate is 30-50 cm, which is favorable for forming a liquid film on the inner wall of the cylinder body by airflow to realize gas-liquid separation.

3) According to the invention, by adopting a multi-stage cyclone design and adjusting the inclination angle between the plane of the cyclone blade and the central axis, the airflow speed of the desulfurized flue gas passing through the demisting cylinder can be changed, the centrifugal speed of the airflow at the upper end of the demisting cylinder when passing through the cyclone is accelerated, and the layered removal of fog drops in the flue gas is realized. The blade inclination angle of the primary cyclone is smaller, so that large liquid drops are removed centrifugally at the lower layer of the tube bundle demisting cylinder as much as possible, the blade inclination angles of the secondary cyclone and the tertiary cyclone are gradually increased, the resistance of airflow passing is increased, the centrifugal speed of airflow passing is accelerated in a turning way, and small liquid drops in the airflow are removed in an accelerating way, and the small liquid drops are removed centrifugally at the upper layer of the tube bundle demisting cylinder.

4) According to the invention, by adopting a multi-stage cyclone design and adjusting the number of the cyclone blades, the airflow speed of the desulfurized flue gas passing through the demisting cylinder can be changed, the centrifugal speed of the airflow at the upper end of the demisting cylinder when passing through the cyclone is accelerated, and the layered removal of fog drops in the flue gas is realized. The number of blades of the primary cyclone is small, large liquid drops are removed by centrifugation at the lower layer of the tube bundle demisting cylinder as much as possible, the large liquid drops are eliminated, the number of blades of the secondary cyclone and the tertiary cyclone is gradually increased, the resistance of airflow passing is increased, the centrifugal speed of airflow passing is accelerated by turning, and therefore small liquid drops in the airflow are removed by acceleration, and the small liquid drops are removed by centrifugation at the upper layer of the tube bundle demisting cylinder. The number of the blades of the cyclone is gradually increased along with the rising of the air flow, so that the pressure drop loss can be reduced as much as possible on the premise of ensuring that demisting reaches the standard, and the gas discharge is facilitated.

5) According to the invention, the blade inclination angles of the first, second and third-stage cyclones are respectively designed to be 25 degrees, 28 degrees and 30 degrees, meanwhile, the blades of the first, second and third-stage cyclones are respectively set to be 15, 18 and 20, and the blade inclination angles and the number of the blades are adjusted, so that the centrifugal liquid removing effect of the cyclones can be fully exerted, the pressure drop loss of air flow is reduced as much as possible, and the flue gas emission after purification is facilitated.

6) The multistage cyclone tube bundle demisting cylinder comprises a tube bundle cylinder body, a converging flow guide device and a cyclone, wherein PP materials are adopted for the cyclone, so that the cyclone is convenient to assemble, install and seal in field installation, is integrally formed through a blade, a central shaft and a cyclone sleeve ring, is convenient for large-scale production and installation, and has high production efficiency.

7) According to the invention, the cyclone, the converging flow guide device and the tube bundle cylinder are symmetrically provided with the internal threaded holes relative to the central axis, and the cyclone, the tube bundle cylinder, the converging flow guide device and the tube bundle cylinder are fixedly connected through bolts, so that the stable operation of the dedusting and demisting cylinder is maintained, and the site construction and installation are facilitated.

8) According to the invention, the tube bundle cylinder can be assembled through the upper cylinder, the lower cylinder and the butt joint ring which are coaxially arranged according to the dust and mist removal requirements in the on-site wet desulfurization tower, so that the mist removal effect can be realized, and the discharge requirements can be met.

9) According to the invention, the blades of the primary and secondary cyclones are connected with the central shaft through the right-handed mode, the blades of the tertiary cyclones are connected with the central shaft through the left-handed mode, and the rotating direction of the blades of the cyclones at the air outlet end of the demisting cylinder is changed, so that the airflow is forced to change the rotating direction of the airflow, the effect of turbulent flow of the airflow can be achieved, and small liquid drops contained in the upper airflow are induced to accelerate centrifugal separation from the airflow, so that the dedusting and demisting effects are improved.

10 The speed increaser is provided with the speed increaser with the height of 10-100 mm, so that the shaping effect on the passing air flow can be better exerted, in addition, the speed increaser is provided with a Venturi cylinder structure, the opening diameter of the air outlet end of the speed increaser is smaller than that of the air inlet end, the rising speed of the passing air flow can be further accelerated, and meanwhile, the contact surface and the contact time between the centrifugal air flow and the inner wall of the speed increaser can be prolonged, thereby being beneficial to liquid separation and improving the dedusting and demisting effects.

11 According to the invention, the converging ring and the guide ring are designed into an asymmetric structure, the height of the converging ring is larger than that of the guide ring, the diameter of the inlet opening of the converging ring is larger than that of the outlet opening of the guide ring, and the contact surface and the contact time between centrifugal airflow and the inner wall of the converging ring can be prolonged, so that the liquid separation is facilitated, and the dust and mist removing effect is improved. The connection part between the speed increasing ring and the converging ring and the guide ring is in arc transition connection, so that separated liquid can smoothly flow down along the inner wall of the converging guide device, and meanwhile, secondary entrainment of air flow is avoided, and the dedusting and demisting effects are good.

12 According to the invention, the inner wall of the guide ring is provided with the guide grooves with the depth of 1-4 mm and 3-8 uniformly distributed, liquid drops in the air flow can be intercepted by the guide grooves, the problem of overlarge thickness of a liquid film on the inner wall of the cylinder body is prevented, and secondary entrainment of the smoke flow is avoided; the rotation direction of guiding gutter is unanimous with the air current whirl direction of passing through, and the guiding gutter passes the speed increaser downwards from the guiding collar exit end and extends to the converging ring entry end, and on the one hand for fog drop and the washing hydroenergy that separates from defogging barrel upper end are fast and are passed through the guiding gutter smoothly and are down, simultaneously, have avoided the secondary of air current to smuggle secretly, in addition, can also reduce the resistance to whirl air current, be favorable to high-speed centrifugal air current to intercept the quick water-dispersing of liquid film that forms, dehydration when flowing through the guiding gutter, dust removal defogging is effectual.

13 The invention adopts a mode of connecting the multi-stage tube bundle cylinders in series, thereby being convenient to install and process, prolonging the height of the tube bundle cylinders according to the removal requirement of on-site clients, ensuring the residence time of air flow in the tube bundle and ensuring the removal efficiency.

Drawings

FIG. 1 is a schematic top view of a prior art tube bundle dust and mist eliminator;

FIG. 2 is a schematic diagram of a prior art tube bundle dedusting and demisting cylinder;

FIG. 3 is a schematic diagram of a dedusting and demisting desulfurizing tower according to an embodiment of the present invention;

FIG. 4 is a schematic view of a gas distribution plate structure of a dedusting and demisting desulfurization tower according to an embodiment of the present invention;

FIG. 5 is a schematic top view of an enlarged partial cell configuration of the gas distribution plate of the present invention;

FIG. 6 is a schematic diagram of the relationship between the upper baffle demister monolithic baffle structure and the lower Fang Chuwu cylinder of an embodiment of the invention;

FIG. 7 is a schematic diagram of a single baffle arrangement of an upper baffle mist eliminator according to one embodiment of the present invention;

FIG. 8 is a schematic top view of the upper fixing plate of the present invention mounted on the tube bundle demisting cylinder;

FIG. 9 is a schematic diagram of the connection between a demister cylinder and upper and lower fixing plates according to the present invention;

( P-P: the upper fixing plate is longitudinally tangent along the central axes of the two opposite angles of the holes )

FIG. 10 is a schematic illustration of the positional relationship of a demister cylinder and a rinse water system of the present invention;

FIG. 11 is a schematic view of a longitudinal section of the present invention taken along the line P-P on the upper mounting plate of FIG. 9;

FIG. 12 is a bottom view of the tube bundle dust and mist eliminator of the present invention after installation;

FIG. 13 is a schematic view of a tube bundle dust and mist eliminator bottom support beam installation according to the present invention;

FIG. 14 is a top view of the present invention after installation of a tube bundle dust and mist eliminator;

FIG. 15 is a schematic view of a tube bundle dedusting and demisting cylinder structure according to the present invention;

FIG. 16 is a schematic view of a vane right-hand cyclone of a tube bundle dedusting and demisting cylinder according to the present invention;

(D-D cyclone longitudinal section along the central axis)

FIG. 17 is a schematic view of the cyclone of FIG. 16 in cross-section in the longitudinal direction D-D along the central axis;

(projection line of E-E cyclone central axis at the connection part of the blade and the inner wall of the cyclone sleeve ring)

FIG. 18 is a schematic view of a vane left-hand cyclone of a tube bundle dedusting and demisting cylinder according to the present invention;

FIG. 19 is a schematic diagram showing a comparison of the connection of the vanes of the present invention to the center shaft for both the left-hand and right-hand swirler vanes;

(1-1: right-hand top view of blade, 1-2 is schematic diagram of connection portion of central shaft and blade of 1-1

2-1, Left-hand top view of blade, 2-2 is schematic diagram of connection part between central shaft and blade 1-1

FIG. 20 is a schematic view of a three-stage swirl tube bundle dedusting and demisting cylinder structure;

FIG. 21 is a schematic diagram of a converging flow guide device for a three-stage tube bundle dedusting and demisting cylinder;

FIG. 22 is a top view of a converging flow guide device for a three-stage tube bundle dedusting and demisting cylinder according to the present invention;

(B-B: longitudinal section line of the converging flow guide device along the center axis)

FIG. 23 is an enlarged partial schematic side view of the converging deflector shown in FIG. 22 from top view A;

FIG. 24 is a schematic cross-sectional view of the converging flow guide device B-B of FIG. 22;

FIG. 25 is a schematic diagram of a converging flow guide device for a three-stage tube bundle dedusting and demisting cylinder according to the present invention;

FIG. 26 is a top view of a converging flow guide device for a three-stage tube bundle dedusting and demisting cylinder according to the present invention.

In the figure: a tube bundle cylinder 1; a lower cylinder 11; an upper cylinder 12; a docking ring 13; a barrel contact end surface 14; a seal 15; a support beam 16; a first blind plate 17; an upper beam 18; a second blind plate 19; a converging and guiding device 2; a confluence ring 21; a deflector ring 22; a speed increaser 23; a confluence ring inlet 211; a confluence ring outlet 212; a deflector ring inlet 221; a deflector ring outlet 222; a diversion trench 223; a cyclone 3; a central shaft 31; a vane 32; a swirl collar 33; a bolt 34; an included angle 35 between projection line E-E and the connection part of the blade and the inner wall of the cyclone sleeve ring; a center shaft-blade connection 36; a primary cyclone 301; a secondary cyclone 302; three stage cyclones 303; an upper fixing plate 4; an upper fixing plate body 41; an upper vent hole 42; an angular aperture 43; a sealing strip 44; a water blocking ring 45; a connecting piece 5; a through hole 51; a bolt 52; a lower fixing plate 6; a lower fixing plate body 61; a lower vent hole 62; a reinforcing rib 63; a flushing water system 7; a water supply pipe 71; a flushing water pipe 72; a water shower head 73; a lower nozzle 74; a flushing water pipe 75; an upper nozzle 76; a desulfurizing tower 8; a desulfurization section 81; a gas distribution plate 811; a third blind plate 8110; an airflow hole 8111; an airflow baffle 8112; a gas baffle 8113; a bolt 8114; a nut 8115; a transition section 82; a defogging section 83; an exhaust stack 84; a flue gas inlet 85; an absorption liquid outlet 86; an absorption liquid inlet 87; an absorption liquid spray head 88; a desulfurization absorbing layer 89; a baffle mist eliminator 9; a baffle 91; the baffle arcuate structure lower edge 92.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required to be used in the embodiments will be briefly described below. It is apparent that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

In describing embodiments of the present invention, the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in terms of orientation or positional relationship shown in the drawings for convenience of description and simplicity of description only, and do not denote or imply that the devices or elements in question must have a particular orientation, be constructed and operated in a particular orientation, so that the above terms are not to be construed as limiting the invention.

The present invention will be described in detail below with reference to the drawings and the specific embodiments, which are not described in detail herein, but the embodiments of the present invention are not limited to the following embodiments.

Embodiment 1

Fig. 3 to 6 are schematic views of a dust-removing demisting desulfurization tower and a gas distribution plate and baffle structure thereof according to embodiment 1 of the present invention. In embodiment 1, a dust-removing, demisting and desulfurizing tower is designed and built, a conventional tube bundle demisting drum is adopted, and a fixing device or a part related to the installation of the conventional tube bundle demisting drum is optimally designed.

As shown in fig. 3, the dedusting and demisting desulfurizing tower is divided into a desulfurizing section 81, a demisting section 83 and a discharge chimney 84 from bottom to top; a tube bundle type dust-removing demister and a baffle plate demister 9 are arranged in the demister section 83, and the baffle plate demister 9 is arranged at a position 1.5m above the tube bundle type dust-removing demister.

The desulfurization section 81 is internally provided with a desulfurization absorption layer 89, the desulfurization absorption layer 89 is a distributed calcium oxide spray system, and the sprayed calcium oxide absorbs sulfides in the flue gas. A gas distribution plate 811 was installed at 2m below the desulfurization absorbing layer 89.

A flue gas inlet 85 is arranged at the lower part of the desulfurization section 81 of the desulfurization tower, a transition section 82 with a trapezoid longitudinal section is also arranged between the flue gas inlet 85 and a gas distribution plate 811, and the height of the transition section 82 is 1.5m; a gas distribution plate 811 is mounted 2.5 meters above the transition section 82. The transition section 82 is of a cylindrical structure with a trapezoid longitudinal section, and the height of the transition section 82 is 200cm.

The demisting section 83 is further provided with a flushing water system 7, which comprises an upper water pipe 71, a flushing water pipeline 72 and a spray head, wherein the flushing water pipeline 72 comprises a one-way flushing water pipeline 75 which is arranged 300-400 mm above the baffle demister 9 and a two-way flushing water pipeline 72 which is arranged between the baffle demister 9 and the tube bundle type dedusting demister, and the spray head is used for flushing the tube bundle type dedusting demister and the baffle demister 9 through the water spray head 73, the upper spray head 76 and the lower spray head 74 respectively.

As shown in fig. 4, a plurality of gas flow holes 8111 with a diameter of 3.8cm are uniformly distributed on the gas distribution plate 811, and the upper and lower sides of the gas distribution plate 811 are divided into a plurality of well-shaped gas flow channels by a plurality of gas baffle plates 8113 and gas flow baffle plates 8112 which are connected in a crisscross manner, wherein the length, width and height of the gas flow channels are 20cm, 20cm and 20cm, respectively.

As shown in fig. 5, two pairs of baffle through holes are symmetrically arranged on the upper and lower sides of the gas distribution plate 811 at intervals of 20cm respectively, the gas flow baffle 8112 is an i-shaped baffle, two pairs of baffle through holes are symmetrically arranged on end plates on both sides of the gas flow baffle 8112, the baffle through holes on the upper and lower sides of the gas distribution plate 811 correspond to the baffle through holes, and the gas baffle 8113 and the gas flow baffle 8112 are fixedly connected through bolts 8114 and nuts 8115.

As shown in fig. 6, the lower edge of the baffle plate 91 of the baffle plate demister 9 is an arc-shaped structure 92 extending in a downward protruding manner, the arc-shaped structure 92 is arranged in the center of the lower edge of the baffle plate 91, a groove-shaped guide rod 93 is connected to the position G1 of the arc-shaped structure 92 of the lower edge of the baffle plate 91 through a buckle 94, the guide rod 93 extends downward to be connected with the lower tube bundle type dedusting demister, the guide rod 93 is made of PP material, the position, close to the upper vent 42 of the upper fixing plate 4 of the tube bundle type dedusting demister, of the lower end of the guide rod 93 is fixed through a connecting piece 95, and the lower end of the guide rod 93 extends downward to the inner wall of the tube bundle type dedusting demister.

In embodiment 1, the induced draft fan blows flue gas into the desulfurization tower 8 from the flue gas inlet 85 of the desulfurization section 81 under induced draft pressure of 7KPa, and after diameter-changing acceleration of the transition section 82 of the desulfurization section 81, the flue gas is subjected to gas flow rectification and uniform distribution by the gas distribution plate 811, and then enters the desulfurization absorption layer 89 for desulfurization. In embodiment 1, the desulfurization absorbing layer 89 is a distributed calcium oxide shower system.

The upper part of the desulfurization section 81 is provided with an absorption liquid inlet 87, the desulfurization absorption liquid enters a distributed calcium oxide spraying system downwards through an absorption liquid spray nozzle 88 to spray the absorption liquid, the ascending flue gas fully contacts with the sprayed calcium oxide in the distributed calcium oxide spraying system, and after sulfide in the flue gas is absorbed by the absorption liquid, the sulfide is discharged from an absorption liquid outlet 86 at the bottom of the desulfurization tower 8 to enter an absorption liquid storage tank. In order to accelerate the absorption of sulfide in the flue gas by the absorption liquid, the absorption liquid spray head 88 may be arranged in multiple layers, for example, 3 layers, and the desulfurization absorption layer 89 is sprayed with the absorption liquid in a layered manner so as to enhance the absorption effect of the distributed calcium oxide spray system.

The desulfurized wet desulfurization flue gas enters a demisting section 83, enters a tube bundle type dedusting demister for centrifugal cyclone separation, and then passes through a baffle plate demister 9 for further demisting, and the rising flue gas flows into the lower layer of a desulfurizing tower to be converged with desulfurization absorption liquid and enters an absorption liquid storage tank after forming a liquid film on the tube wall of the tube bundle type dedusting demister and a baffle plate 91 of the baffle plate demister 9. In order to ensure the demisting effect of the tube bundle type dust-removing demister and the baffle demister 9, a flushing water system 7 needs to be started periodically, and fog drops hanging on the tube wall of the tube bundle type dust-removing demister and the inner wall of the baffle demister 9 are flushed. The purified flue gas defogged by the baffle defogger 9 is exhausted through the exhaust stack 84.

In embodiment 1, the desulfurization tower can remove gypsum rain and realize ultra-low emission by the cooperative demisting of the tube bundle dust removal demister and the baffle demister. The lower edge of the baffle plate demister is designed into an arc-shaped structure protruding downwards and is connected with a groove-shaped guide rod, so that liquid drops condensed on the baffle plate can flow to the arc-shaped structure along the lower edge of the baffle plate and flow to the inner wall of the lower tube bundle demisting cylinder body along the groove of the guide rod to the desulfurization section, the probability of secondary fog drop entrainment of the baffle plate demister is reduced, and the ultra-low standard emission of flue gas is ensured.

Embodiment 2

FIG. 7 is a schematic view of the structure of a single baffle of an upper baffle mist eliminator in embodiment 2 of the present invention. Unlike embodiment 1, in embodiment 2, the structure of the damper 91 is optimized. As shown in fig. 7, a circular arc structure 92 is provided at a lower edge of the baffle plate 91 with a distance of 40cm, and guide rods are installed at protruding points G1, G2 of the circular arc structure 92.

The lower edge of the baffle plate 91 of the baffle plate demister 9 is designed into an arc-shaped structure 92 protruding downwards in a segmented mode and is connected with a groove-shaped flow guide rod 93, so that small liquid drops trapped on the baffle plate 91 can be accelerated to flow to the arc-shaped structure 92 along the lower edge of the baffle plate 91 and quickly flow to the inner wall of the lower tube bundle cylinder 1 along the groove of the flow guide rod 93, the problem that secondary fog drops are entrained in the baffle plate demister 9 is avoided, gypsum rain is thoroughly eliminated, and ultra-low standard emission of flue gas is ensured.

Embodiment 3

Fig. 8 is a schematic diagram showing connection and installation relationship of components such as a tube bundle type dust and mist eliminator and an upper fixing plate according to embodiment 3 of the present invention.

Unlike embodiment 2, in embodiment 3, a conventional tube bundle demister tube is used, and a fixing device or a component involved in the installation thereof is optimally designed.

Fig. 8 is a schematic plan view showing the structure of the upper fixing plate in embodiment 3 after installation, showing the connection relationship between the upper fixing plate and the tube bundle cylinder of the tube bundle dust-removing mist eliminator.

As shown in fig. 8, a tube bundle dust-removing and demisting component such as a cyclone 3 is mounted in a tube bundle cylinder 1 with an opening diameter d=400 mm and a wall thickness of 0.5cm in advance, and 4 tube bundle cylinders 1 are positioned in a desulfurization device according to design requirements. The square upper fixing plate 4 with the side length of 450mm, which is provided with an internal thread angle hole 43 with the diameter of 1.5cm and an upper vent hole 42 with the diameter of 36cm at the center of the upper fixing plate body 41, is symmetrically arranged at the angle 4, is fixed on the tube bundle cylinder 1 in a sealing way, the upper vent hole 42 is opposite to the top end opening of the tube bundle cylinder 1, the upper vent hole 42 is coaxial with the tube bundle cylinder 1, and the connecting part between the adjacent upper fixing plates 4 is sealed by adopting a sealing strip 44. After the adjacent 4 upper fixing plates 4 are assembled together, 4 corner hole structures are formed at the connecting positions, the square connecting sheet 5 is arranged at the 4 corner hole structure positions, 4 through holes 51 with the diameters close to or slightly larger than the inner diameters of the corner holes are formed at the corresponding positions of the 4 corner holes 43 and the connecting sheet 5, and the connecting sheet 5 and the 4 upper fixing plate bodies 41 are fixed by bolts 52, so that the upper end integrated sealing structure of the tube bundle dust-removing demister is completed.

In embodiment 3, the tube bundle dust removal defroster, including last fixed plate 4, tube bundle defogging section of thick bamboo 1, connection piece 5 etc. all adopt corrosion-resistant PP material preparation, can satisfy batch production, on-the-spot modularization equipment, low in labor strength, accord with the operating mode requirement of flue gas desulfurization environment.

Embodiment 4

Fig. 9 to 14 are schematic views showing connection and installation relationships of the tube bundle type dust and mist eliminator and the upper and lower fixing plates according to embodiment 4 of the present invention.

Unlike this embodiment 3, the desulfurizing tower 8 in embodiment 4 is a technical modification of the existing desulfurizing tower, the main structure of the roof-ridge type demister is removed, the support beam 16 is retained, and the tube-bundle type dust-removing demister is designed and installed on the support beam 16, and the baffle demister 9 is installed above the tube-bundle type dust-removing demister. In addition, the structure of the air outlet end of the tube bundle defogging cylinder is improved by a fixing device or a part related to the installation of the tube bundle defogging cylinder.

As shown in fig. 9, in embodiment 4, a tube bundle tube 1 is assembled from a lower tube 11 and an upper tube 12, the joint is connected by a butt ring 13 and sealed by a seal 15, a tube contact end surface 14 of the lower tube 11 and the upper tube 12 is sealed by a sealant, and the butt ring 13 is fixed to the lower tube 11 and the upper tube 12 by bolts (not shown).

As shown in fig. 9, the upper fixing plate body 41 of the square upper fixing plate 4 with the side length of 450mm is provided with an upper vent hole 42 with the diameter of 36cm, the upper fixing plate 4 is arranged at the top end of the upper cylinder 12, the upper vent hole 42 is fixedly connected with the upper cylinder 12 coaxially, and the contact part is sealed by sealant.

As shown in fig. 9, a lower vent hole 62 with a diameter of 40cm, which is similar to the opening diameter of the lower cylinder 11, is formed in the center of the lower fixing plate body 61 of the square lower fixing plate 6 with a side length of 450mm, the lower fixing plate 6 is placed at the bottom of the lower cylinder 11, the lower vent hole 62 and the lower cylinder 11 are kept coaxially and fixedly connected, and the contact part is sealed by sealant. Right triangle reinforcing ribs 63 are symmetrically arranged and vertically arranged on the 4 corners of the inner surface of the lower fixing plate body 61, and the reinforcing ribs 63 are welded on the outer cylinder walls of the lower fixing plate body 61 and the tube bundle cylinder 1 through plastics.

As shown in fig. 9, the desulfurization flue gas enters from the lower vent holes 62 of the lower fixing plate body 61, passes through the lower cylinder 11 and the upper cylinder 12, is subjected to gas-liquid cyclone separation, and is discharged from the upper vent holes 42 of the upper fixing plate body 41.

Fig. 10 is a schematic view showing a positional relationship between a demister cylinder and a washing water system according to embodiment 4 of the present invention. In the present embodiment, the flushing water system 7 is installed above the upper fixing plate 4 at a position of 4500mm, flushing water is supplied through the water supply pipe 71 and the flushing water pipe 72, and the water is periodically sprayed through the water spray head 73 to the gas flow separated from the gas-liquid discharged from the upper vent hole 42 of the upper fixing plate body 41, so that dust and mist liquid adhering to the inner wall of the tube bundle cylinder 1 during the gas-liquid cyclone separation process of the upper cylinder 12 and the lower cylinder 11 can be flushed and removed, and fine liquid droplets entrained in the gas flow during the rising process can be further absorbed, thereby ensuring the ultra-low emission of the desulfurized flue gas. In the present embodiment, the interval distance between the adjacent two water spray nozzles 73 on the wash water pipe 72 is 30cm. The distance design of the water spray head 73 is adjusted according to the demisting index control requirement by combining the structure and the size of the on-site desulfurizing tower and the working condition of the demister so as to meet the ultra-low emission target of flue gas.

FIG. 11 is a schematic view showing a longitudinal section along P-P on the upper fixing plate in FIG. 9 according to an embodiment of the present invention. As can be seen from fig. 11, the contact portion between the upper fixing plate body 41 and the tube bundle cylinder 1 is in sealing connection, since the upper vent hole with the diameter d2 of 36cm is formed in the center of the upper fixing plate body 41, and the diameter d1 of the opening of the tube bundle cylinder below is 40cm, the tube bundle cylinder 1 after the upper fixing plate 4 is mounted forms a water retaining ring 45 at the opening of the upper end, and the ring width of the water retaining ring 45 is half of the difference between d1 and d2, in this embodiment, the ring width of the water retaining ring 45 is 2cm. The water retaining ring can be naturally formed by utilizing the design that the contact part of the upper fixing plate 4 and the tube bundle cylinder body 1 passes through the opening diameter, the structure is simple, the construction is convenient, and the liquid film formed on the inner wall of the tube bundle cylinder body 1 can be effectively prevented from being carried out by gas to form secondary entrainment.

In fig. 11, the cyclone 3 is mounted at the inner outlet end of the tube bundle cylinder 1 and is fixed by bolts 34. The vertical distance h between the upper end of the cyclone 3 and the upper fixing plate 1 is 40cm, so that the centrifugal cyclone airflow from the cyclone 3 can continuously ascend along the inner wall of the tube bundle cylinder 1, the airflow can form a liquid film on the inner wall of the cylinder, and gas-liquid separation can be realized by flushing water of the water spray head 73 above the cylinder at regular intervals.

Fig. 12 is a bottom view of the tube bundle dust and mist eliminator according to embodiment 4 of the present invention after installation, fig. 13 is a schematic view of the tube bundle dust and mist eliminator bottom support beam installation according to the present embodiment, and fig. 14 is a top view of the tube bundle dust and mist eliminator according to the present embodiment after installation.

According to fig. 12 to 14, the tube bundle type dedusting demister of the present invention is modified based on a conventional desulfurizing tower, and the main structure of the original ridge demister is removed, leaving a supporting beam 16 (see fig. 12). The tube bundle type dedusting demister is arranged on a supporting beam 16 of a demisting section 83 in a desulfurizing tower 8 and comprises an upper fixing plate 4, a tube bundle demisting cylinder 1 and a lower fixing plate 6 which are sequentially connected; the tube bundle demisting cylinders 1 with the opening diameter of 40cm and the cylinder wall thickness of 0.5cm are fixed on the supporting beams 16 through the lower fixing plates 6, the supporting beams 16 horizontally span the inner wall of the desulfurizing tower 8, and a plurality of tube bundle demisting cylinders 1 are connected in parallel through the upper fixing plates 4 and the lower fixing plates 6; circular upper vent holes 41 (hole diameter is 36 cm) and circular lower vent holes 61 (hole diameter is 40 cm) are respectively and penetratingly arranged in annular rings formed at the connecting parts of the tube bundle defogging cylinder 1 and the upper fixing plate 4 and the lower fixing plate 6; the upper fixing plate 4 and the lower fixing plate 6 are square plates with equal side length larger than the outer diameter of the tube bundle demister 1, and in the embodiment, the side length of each square plate is 45cm and the thickness is 0.5cm; the distance between two adjacent support beams 16 is 40cm.

As shown in fig. 14, after the main structure of the tube bundle type dust and mist eliminator is installed, the second blind plate 19 is used for sealing the gap between the inner wall of the desulfurizing tower 8 and the tube bundle cylinder 1 or the upper fixing plate 4, and the gap is fixed by bolts and connecting sheets. As shown in fig. 12, after the tube bundle type dust and mist eliminator main body structure is installed, the first blind plate 17 is used for sealing the gap between the inner wall of the desulfurizing tower 8 and the tube bundle cylinder body 1 or the lower fixed plate 6, and in order to enhance the stability of the tube bundle type dust and mist eliminator, in this embodiment, after the upper fixed plate 4 is installed, two upper beams 18 are additionally installed for reinforcing the tube bundle type dust and mist eliminator main body structure.

In embodiment 4, the tube bank formula dust removal defroster, including last fixed plate 4, tube bank defogging section of thick bamboo 1, connection piece 5, lower fixed plate 6, strengthening rib 63, wash pipe etc. all adopt corrosion-resistant PP material preparation, can satisfy batch production, on-the-spot modularization equipment, low in labor strength, accord with the operating mode requirement of flue gas desulfurization environment. The existing desulfurizing tower 8 is technically modified, the upper part of the existing desulfurizing tower 8 can be additionally provided with the discharge chimney 84, the original chimney can be used for discharging, the construction is convenient, and the investment is small.

Embodiment 5

Fig. 15 to 19 are schematic views of a three-stage cyclone tube bundle dust and mist removing cylinder structure and a related cyclone structure, which are core components of the tube bundle dust and mist remover according to embodiment 5 of the present invention. Unlike embodiment 4, embodiment 5 is a modified embodiment in which a single-stage demister tube is used as the tube bundle tube 1, and the interior demister member of the tube bundle demister tube 1 is further modified.

As shown in fig. 15, the tube bundle dedusting and demisting cylinder with the opening diameter d=400 mm and the wall thickness of 0.5cm comprises a tube bundle cylinder 1, a converging flow guiding device 2, a primary cyclone 301, a secondary cyclone 302 and a tertiary cyclone 303; the tube bundle cylinder body 1 is a hollow cylinder with two open ends, and a primary cyclone 301, a converging flow guiding device 2, a secondary cyclone 302, a converging flow guiding device 2 and a tertiary cyclone 303 are coaxially arranged in the tube bundle cylinder body 1 at intervals in sequence from bottom to top. In the present embodiment, the number of blades 32 of each stage of the cyclone increases in order in the direction of the air flow, and the number of blades of the first, second and third stage of the cyclone is 15, 18 and 20, respectively.

As shown in fig. 15, the converging flow guide device 2 is a cylinder with smooth inner walls and two open ends, and comprises a converging ring 21, a flow guide ring 22 and a speed increaser 23, which are manufactured by integral molding. In the present embodiment, the converging ring 21 and the guide ring 22 are of a funnel-shaped structure with both ends open and symmetrical to the speed increaser 23, the converging ring 21 and the guide ring 22 are connected by a reduced diameter portion of the funnel-shaped structure, the diameter of the opening of the reduced diameter portion is 60% of the diameter of the inlet of the converging ring 21, and the reduced diameter portion naturally forms the speed increaser 23. In this embodiment, the converging deflector 2 is mounted above the cyclone, preferably directly abutting the end face of the cyclone collar.

As shown in fig. 16, the primary, secondary and tertiary cyclones each include a central shaft 31, vanes 32 and a swirl collar 33; the blades 32 are arranged in a ring around the central shaft 31, are mounted on the central shaft 31 in an inclined manner, and the swirl collar 33 is fixed to and coaxially connected with the central shaft 31 by the blades 32. For easy processing and installation, the blades 32, the central shaft 31 and the swirl collar 33 of the primary, secondary and tertiary swirlers are integrally formed. In the embodiment, the relative positions of the cyclone 3 and the tube bundle cylinder 1 are symmetrically drilled with 3-4 internal threaded holes relative to the central axis, and the internal threaded holes are fixedly connected through bolts 34, so that the on-site construction is convenient, and the stable operation of the demisting cylinder can be met.

As shown in fig. 17, the blade 32 has a propeller type inclined blade structure, and an inclination angle (i.e., a blade inclination angle) formed between a plane in which the blade 32 is located and a central axis is an acute angle. For ease of illustration, in fig. 17, E-E is the projection line of the central axis of the cyclone at the connection between the vane 32 and the inner wall of the cyclone collar 33, and β is the angle 35 between the projection line E-E and the connection between the vane 32 and the inner wall of the cyclone collar 33, which is equal to the inclination angle of the plane of the vane 32 with respect to the central axis, so β may be used to represent the inclination angle of the vane. The blade pitch angle of the primary cyclone 301 is 25 °, the blade pitch angle of the secondary cyclone 302 is 28 °, and the blade pitch angle of the tertiary cyclone 303 is 30 °.

In embodiment 5, the rotational direction of the blades of the cyclone 3 is changed, and the centrifugal airflow rising through the cyclone 3 is disturbed by connecting the blades with the central shaft 31 in a right-handed or left-handed manner, thereby achieving the purpose of accelerating gas-liquid separation, particularly droplet separation. As shown in fig. 15, the vanes 32 of the primary cyclone 301 and the secondary cyclone 302 are connected to the central shaft 31 by a right-hand rotation, and the vanes 32 of the tertiary cyclone 303 are connected to the central shaft 31 by a left-hand rotation. Fig. 16 and 18 schematically illustrate the overall effect of two different vane rotation mode cyclones mounted on a demister cylinder, respectively. Fig. 19 compares the relative positional relationship of the connection part 36 between the blades 32 and the central shaft 31 of the two swirlers with different blade rotation modes, and the rotation direction of the air flow can be changed to achieve the purposes of forced turbulence and separation of small liquid drops.

In embodiment 5, the confluence deflector 2 is connected to the tube bundle cylinder 1 by bolts (not shown in fig. 15), and internal threaded holes 3 to 4 are symmetrically bored with respect to the central axis at the opposite positions of the confluence deflector 2 and the tube bundle cylinder 1, and are fixedly connected by bolts in a manner similar to the manner in which the cyclone 3 and the tube bundle cylinder 1 are fixed.

In embodiment 5, multistage whirl tube bank defogging section of thick bamboo, including tube bank barrel 1, collection flow guiding device 2, swirler 3 all adopt corrosion-resistant PP material preparation, can satisfy batch production, on-the-spot modularization equipment, low in labor strength, accord with the operating mode requirement of flue gas desulfurization environment.

Embodiment 6

Fig. 20 is a schematic view of a three-stage swirl structure tube bundle dust and mist removing cylinder, which is a core component of the tube bundle dust and mist remover according to embodiment 6 of the present invention. Unlike embodiment 5, the tube bundle tube 1 is assembled in multiple stages to form a demister tube. Mainly has the following aspects:

as shown in fig. 20, the tube bundle cylinder 1 includes an upper cylinder 12, a lower cylinder 11, and a docking ring 13 coaxially disposed. The upper cylinder 12 and the lower cylinder 11 are nested in the docking ring 13, the upper cylinder 12 and the lower cylinder 11 are connected through a cylinder contact end surface 14 by adopting sealant, the contact parts of the upper cylinder 12, the lower cylinder 11 and the docking ring 13 are sealed through a sealing piece 15, and in the embodiment, the sealing piece 15 is a plastic welding seal. During field installation, the cyclone 3 and the confluence flow guiding device 2 in the upper cylinder 12 and the lower cylinder 11 are installed according to the design requirement, the butt joint ring 13 is sleeved at the upper end of the lower cylinder 11 and fixed through bolts (not shown in the figure), a layer of sealant is smeared on the upper end face of the lower cylinder 11, then the upper cylinder 12 is sleeved in the butt joint ring 13 and fixed through bolts (not shown in the figure), and finally the contact parts of the upper cylinder 12, the lower cylinder 11 and the butt joint ring 13 are sealed through plastic welding.

In embodiment 6, the tube bundle cylinder 1 is assembled by splicing the upper cylinder 12 and the lower cylinder 11, so that the height of the demisting cylinder can be flexibly adjusted according to the site requirement, and the effect of gas-liquid separation is achieved. In addition, the device is convenient to produce, transport and install on site by sectional assembly.

Embodiment 7

Unlike embodiment 5, the speed increaser is structured differently. In embodiment 7, the speed increaser 23 is a cylindrical structure, and is provided with a speed increasing ring with a height of 10-100 mm, the flow guiding ring 22 and the converging ring 21 are in a funnel shape with symmetrical design, the diameter of the upper opening of the speed increasing ring is the same as the diameter of the inlet of the flow guiding ring 22, the diameter of the lower opening of the speed increasing ring is the same as the diameter of the outlet of the converging ring 21, and the connection parts of the speed increasing ring, the converging ring 21 and the flow guiding ring 22 are in transitional connection through an arc.

The speed increaser 23 is expanded into a speed increaser ring with the diameter of 10-100 mm, so that the shaping effect on the passing air flow can be better exerted, and the gas-liquid separation is facilitated.

Embodiment 8

Fig. 21 is a schematic structural diagram of a converging and guiding device for a three-stage tube bundle dust and mist removing cylinder, which is a core component of the tube bundle dust and mist removing device in embodiment 8 of the present invention. This embodiment differs from embodiment 7 mainly in the structure of the confluence flow guiding device 2.

As shown in fig. 21, the converging ring 21 and the guide ring 22 are of an asymmetric structure with respect to the speed increaser 23, the speed increaser 23 is a venturi-type speed increaser with a height of 100mm, and the guide ring 22 and the converging ring 21 are of an asymmetric funnel-shaped design. The diameter of the upper opening of the speed increasing ring is smaller than that of the lower opening of the speed increasing ring, the connection parts of the speed increasing ring, the converging ring 21 and the guide ring 22 are in arc transition connection, and the diameter of the inlet opening of the converging ring 21 is the same as that of the outlet opening of the guide ring 22.

The speed increaser is expanded into a Venturi speed increaser with the diameter of 100mm, so that the shaping effect on the passing airflow can be better exerted, the rising speed of the passing airflow can be further accelerated, the collision opportunity between fog drops in the airflow and the inner wall of the speed increaser is increased, the contact surface and the contact time between centrifugal airflow and the inner wall of the speed increaser are prolonged, and the liquid separation is facilitated, and the dedusting and demisting effects are improved.

Embodiment 9

Fig. 22 to 24 are schematic views showing a structure and a partial enlarged view of a converging flow guide device for a three-stage tube bundle dust and mist removing cylinder, which is a core component of the tube bundle dust and mist removing device according to embodiment 9 of the present invention. This embodiment differs from embodiment 8 mainly in the structure of the converging flow guide device 2.

First, as shown in fig. 22, 3 strip-shaped guide grooves 223 are uniformly and equally spaced on the inner wall of the guide ring 22, as shown in fig. 23, the depth of the guide groove is 2mm, the cross section of the guide groove is circular arc, as shown in fig. 24, the guide groove 223 extends from the guide ring outlet 222 to the guide ring inlet 221 of the inner wall of the guide ring 22, and continuously passes through the inner wall of the speed increasing ring downwards along the inner wall of the converging guide device 2, and extends to the inlet end 211 of the converging ring 21 through the outlet end 212 of the converging ring 21. The design can accelerate the separated fog drops to flow down along the diversion trench, and avoid and reduce the problem of secondary entrainment of the fog drops. In addition, evenly distributed's guiding gutter can also prevent to appear the too big problem of liquid film thickness on the barrel inner wall, and dust removal defogging is effectual.

Second, the height of the converging ring 21 is larger than that of the guiding ring 22, and the diameter of the opening of the inlet end 211 of the converging ring 21 is larger than that of the opening of the outlet end 222 of the guiding ring 22. The design can fully confluence air flow and accelerate air flow to centrifugally separate liquid.

Embodiment 10

Fig. 25 to 26 are schematic structural views of a converging flow guiding device for a three-stage tube bundle dust and mist removing cylinder, which is a core component of the tube bundle dust and mist removing device according to embodiment 10 of the present invention. The difference of this embodiment is mainly that the flow guide groove 223 of the confluence flow guide device 2 is structurally different from embodiment 9.

In embodiment 10, 4 spiral guide grooves 223 are uniformly and equally spaced on the inner wall of the guide ring 22, the depth of the guide grooves is 4mm, the rotation direction of the spiral is identical to the rotational flow direction of the passing air flow, and the guide grooves 223 extend from the guide ring outlet 222 on the inner wall of the guide ring 22 to the guide ring inlet 221.

The flue gas treatment process flow using the embodiment of the invention is as follows:

After denitration treatment, flue gas from boiler combustion firstly passes through electrostatic dust removal by a cloth bag, induced air by an induced draft fan and then enters a dust removal and demisting desulfurization tower for wet desulfurization treatment to form desulfurization flue gas with certain dust and fog, and after the desulfurization flue gas passes through a tube bundle type dust removal demister and a baffle plate demister in sequence for further dust removal and demisting treatment, the flue gas ultra-low emission requirement is met.

After the flue gas enters the desulfurizing tower from the desulfurizing section, the flue gas passes through the transition Duan Daoliu, is rectified and uniformly distributed through the gas distribution plate after being accelerated, then enters the desulfurizing absorption layer, fully contacts with sprayed and discharged calcium oxide absorption liquid in the distributed calcium oxide spraying system, the desulfurized wet desulfurization flue gas rises and enters the demisting section after being absorbed by the absorption liquid, the desulfurized wet desulfurization flue gas firstly passes through the tube bundle type dedusting demister to carry out three-stage centrifugal cyclone separation to collect large liquid drops, then passes through the baffle plate demister to further remove fine liquid drops, and the rising flue gas flows into the lower layer of the desulfurizing tower to be converged with the desulfurizing absorption liquid into the absorption liquid storage tank after forming a liquid film on the tube wall of the tube bundle type dedusting demister and the baffle plate of the baffle plate demister.

In order to ensure the demisting effect of the tube bundle type dust-removing demister and the baffle plate demister, a flushing water system is started regularly to flush fog drops on the tube wall of the tube bundle type dust-removing demister and the baffle plate of the baffle plate demister. The purified flue gas after demisting by the baffle demister can be basically removed, and finally the flue gas is exhausted through an exhaust chimney.

The wet desulfurization flue gas treated by the method can thoroughly eliminate gypsum rain after measurement. When the dust content before the inlet of the desulfurization absorption tower is less than or equal to 50mg/Nm ³, the concentration of smoke fog drops at the outlet of the desulfurization tower can be reduced to be less than 75mg/Nm ³ in winter, and can be reduced to be less than 25mg/Nm ³ in summer, and the concentration of smoke can be reduced to be less than 5mg/Nm ³ by adopting an extraction type measurement method, so that the dust content at the outlet of the high-efficiency tube-bundle type dedusting demister is less than or equal to 5mg/Nm ³.

Comparative examples

In order to compare the dedusting and demisting effects between the invention and the prior art. The applicant compared the demisting results of a desulfurizing tower using a conventional demister, a desulfurizing tower replacing a ridge type demister, and embodiment 9 (a tube bundle type dust removal demister and baffle demister composite demister) according to the present invention at the same desulfurizing tower inlet dust content of 50mg/Nm ³. The specific results are shown in Table 1.

Table 1 results of comparing dedusting and demisting effects before and after improvement of desulfurizing tower technology

The traditional demister works by means of inertia action and gravity action of liquid drops in the flue gas. The design flow rate is typically selected to be between 3.5 and 5.5 m/s. The operating principle and the operating flow rate of the foldback demister determine that fine liquid drops cannot be removed, and even the multi-layer ridge type demister cannot achieve the outlet dust concentration of 10mg/Nm ³. And the desulfurization tower which adopts the technical transformation of the tube bundle type dedusting demister and the baffle plate demister and the dedusting demisting integrated desulfurization tower which is used for carrying out the technical transformation on the baffle plate can realize the coupling effect of the tube bundle demisting and the baffle plate demisting, and the dust concentration of a flue gas outlet can reach below 5mg/Nm ³. In addition, the tube bundle type dust removal demister and baffle demister are adopted for composite dust removal demisting, and the flushing frequency, the flushing water quantity and the number of flushing water electric valves are smaller than those of a conventional ridge type demister.

The above description is only one embodiment of the present invention and is not intended to limit the present invention, and various modifications and variations of the present invention will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A dedusting and demisting desulfurizing tower, which comprises a desulfurizing section (81), a demisting section (83) and an exhaust chimney (84) which are sequentially communicated; the demisting section (83) is provided with a tube bundle type dedusting demister and a baffle demister (9), the baffle demister (9) is arranged above the tube bundle type dedusting demister, and the interval between the baffle demister (9) and the tube bundle type dedusting demister is 1-1.8 m;

the lower edge of a baffle plate (91) of the baffle plate demister (9) is provided with an arc-shaped structure (92) which protrudes downwards, a groove-shaped guide rod (93) is connected to the arc-shaped structure (92) at the lower edge of the baffle plate (91), and the guide rod (93) extends downwards to be connected with the inner wall of the lower tube bundle type dedusting demister;

The tube bundle type dust removal demister comprises an upper fixing plate (4), tube bundle demisting drums and a lower fixing plate (6), wherein the tube bundle demisting drums are connected in parallel through the upper fixing plate (4) and the lower fixing plate (6); the tube bundle demisting cylinder is a multi-stage rotational flow tube bundle demisting cylinder and comprises a tube bundle cylinder body, a converging flow guide device and at least two stages of cyclones; the converging flow guide device is a hollow cylinder with two open ends, a reduced middle diameter and a smooth inner wall and comprises a converging ring, a flow guide ring and a speed increaser; the speed increaser is a speed increaser with the height of 10-100 mm and is positioned between the converging ring and the guide ring.

2. The dedusting and demisting desulfurizing tower according to claim 1, wherein the demisting section (83) is further provided with a flushing water system (7) comprising a water supply pipe (71), a flushing water pipeline and a nozzle which are sequentially connected, and the nozzle is used for flushing the tube bundle dedusting demister and the baffle demister (9) through the water nozzle (73), the upper nozzle (76) and the lower nozzle (74) respectively.

3. The dedusting and demisting desulfurization tower according to claim 1, wherein a desulfurization absorption layer (89) is arranged in the desulfurization section (81), and the desulfurization absorption layer (89) is a distributed calcium oxide spray system.

4. A dedusting and demisting desulfurizing tower according to claim 3, wherein a gas distribution plate (811) is further arranged 1.5-2.5 m below the desulfurizing absorption layer (89), and a plurality of gas flow holes (8111) with diameters of 2-5 cm are uniformly distributed on the gas distribution plate (811).

5. The dedusting and demisting desulfurization tower according to claim 4, wherein the upper and lower sides of the gas distribution plate (811) are divided into a plurality of groined-shaped gas flow channels by a plurality of gas baffles (8113) and gas flow separators (8112) which are vertically and horizontally connected, and the length, width and height of the gas flow channels are 20-40 cm, 20-40 cm and 10-20 cm, respectively.

6. The dedusting and demisting desulfurizing tower according to claim 5, wherein two pairs of baffle through holes are symmetrically arranged on the upper side and the lower side of the gas distribution plate (811) at intervals of 20-40 cm respectively, the gas flow baffle (8112) is an I-shaped baffle, two pairs of baffle through holes are symmetrically arranged on end plates on the two sides of the gas flow baffle (8112), the baffle through holes on the upper side and the lower side of the gas distribution plate (811) correspond to the baffle through holes, and the gas baffle (8113) and the gas flow baffle (8112) are fixedly connected through bolts (8114) and nuts (8115).

7. The dedusting and demisting desulfurization tower according to any one of claims 1 to 6, characterized in that the arc-shaped structure (92) is arranged in the center of the lower edge of the baffle (91) or at intervals of 40 to 50 cm.

8. The dedusting and demisting desulfurization tower according to claim 7, wherein the guide rod (93) is made of PP material.

9. The dedusting and demisting desulfurizing tower according to claim 8, wherein the upper end of the guide rod (93) is connected with the arc-shaped structure (92) at the lower edge of the baffle plate (91) through a buckle (94), and the part of the lower end, which is close to the upper vent hole (42) of the upper fixing plate (4) of the tube bundle dedusting and demister, is fixedly connected through a connecting piece (95).

10. The dedusting and demisting desulfurization tower according to claim 1 or 9, wherein the upper fixing plate (4) and the lower fixing plate (6) are square plates with side lengths larger than the outer diameter of the tube bundle demisting drum.