CN111905490A - Slag extractor mechanism for HMC pulse single-machine dust collector and implementation method thereof - Google Patents

Abstract

The invention discloses a slag discharging mechanism for a HMC pulse single-machine dust collector and an implementation method thereof, belonging to the technical field of HMC pulse single-machine dust collectors. According to the slag discharging mechanism for the HMC pulse single-machine dust collector and the implementation method thereof, the slag discharging mechanism can disperse the blocking object at the slag discharging opening and discharge the blocking object into the slag collecting bin from the slag discharging opening, so that the problem that the slag discharging opening of the traditional HMC pulse single-machine dust collector is easy to block and cannot discharge slag can be effectively solved, the smooth slag discharging work of the HMC pulse single-machine dust collector can be effectively ensured, the slag discharging speed is high, and the slag discharging efficiency is greatly improved.

Description

Slag extractor mechanism for HMC pulse single-machine dust collector and implementation method thereof

Technical Field

The invention relates to the technical field of HMC pulse single-machine dust collectors, in particular to a slag extractor mechanism for an HMC pulse single-machine dust collector and an implementation method thereof.

Background

The HMC type single-machine pulse dust collector is a small-sized bag dust collector designed after improvement. The technology of blowing and cleaning ash by high-pressure (0.5-0.7MPa) large-flow pulse valves one by one filter bag is adopted, and the device has the characteristics of large ash cleaning kinetic energy, light weight, small volume, simple and compact structure, easy installation, convenient maintenance (external filtering type) and high ash cleaning efficiency.

The working principle of the HMC type single-machine pulse dust collector is as follows: the dust-containing gas enters the dust hopper from the air inlet or enters the filter bag chamber through the open flange opening, and the dust-containing gas is filtered into clean gas through the filter bag, enters the air purifying chamber, passes through the clean gas exhaust opening and is exhausted by the fan. The dust is accumulated on the outer surface of the filter bag and is increased continuously, so that the resistance of the filter bag dust remover is increased continuously, and the dust on the filter bag needs to be removed periodically so that the resistance of the filter bag dust remover does not exceed 1200Pa and the filter bag dust remover can continue to work. The ash cleaning is that a program controller starts a pulse valve in sequence at regular time, so that compressed air (0.5-0.7MPa) in a bag is sprayed out from a spraying hole (called primary air) and induces ambient air (called secondary air) which is several times of one flash air into a filter bag through a venturi tube, so that the filter bag expands rapidly in a moment, and dust is shaken off along with the reverse action of airflow, thereby achieving the aim of cleaning ash.

Chinese patent No. CN209155350U discloses a single-machine pulse dust collector, the air passes through the air inlet and gets into the dust removal case, carry out the large granule dust through the division board and filter, carry out the tiny particle filtration through the filter bag again, and discharge through the gas vent, and make the air pump produce the pulse air current and spout through the shower nozzle of blowing through pulse control appearance and electromagnetic pulse valve, carry out reverse impact to division board and filter bag, make the impurity attached to on it drop into and receive the dirt fill, extension single use time, improve work efficiency, but, this single-machine pulse dust collector is when using, because lack corresponding row's sediment mechanism, make this single-machine pulse dust collector when using, its row's cinder notch easily blocks up and leads to the unable smooth discharge of lime-ash, make row's sediment speed slow, and then reduced the efficiency of arranging the sediment.

Chinese patent No. CN203750351U discloses a side air intake type single-machine pulse dust collector, which is formed by connecting each component by welding into a rigid body, and has the advantages of good dust removing effect, high dust removing efficiency (up to 99.9%), small volume, light weight, low cost and strong capability of treating smoke dust, along with the difference of using filter materials, the using temperature range can reach 80-200 ℃, the using range is wide, the service life of the device is long, the device is safe and reliable to operate, and the device can be used for dust removing purification and material recovery of non-fiber industrial dust of various industrial and mining enterprises such as metallurgy, building materials, machinery, chemical engineering, mines and the like.

Therefore, a slag discharging mechanism for a HMC pulse single-machine dust collector and an implementation method thereof are urgently needed to solve the problems, so that the smooth operation of slag discharging of the HMC pulse single-machine dust collector can be effectively ensured, the slag discharging speed is high, and the slag discharging efficiency is greatly improved.

Disclosure of Invention

The invention aims to provide a slag discharging mechanism for an HMC pulse single-machine dust collector and an implementation method thereof.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a slag discharging mechanism for HMC pulse unit dust collector, includes the dust remover, be provided with air inlet and gas vent on the dust remover, the air inlet is located the lower extreme of dust remover, the gas vent is located the upper end of dust remover, the lower surface mounting of dust remover has parallel arrangement's stabilizer blade, the lower extreme of dust remover still is provided with the ash bucket, the ash bucket is located the inboard of parallel arrangement's stabilizer blade, be provided with the cinder notch on the ash bucket, the below of cinder notch is provided with slag discharging mechanism, slag discharging mechanism passes through bracing piece A and bracing piece B to be fixed on the stabilizer blade, the lower extreme of stabilizer blade is provided with supporting component, the last collection cinder storehouse of having placed of supporting component, the collection cinder storehouse is located slag discharging mechanism under.

Further, the slag discharging mechanism comprises a fixed box, a driving motor, a screw rod, a moving block, a guide seat, a supporting seat and a slag discharging assembly, the fixed box is installed on the supporting rod A and the supporting rod B, the driving motor is installed on the inner wall of the fixed box, the screw rod is installed on an output shaft of the driving motor through a coupler, the upper end of the screw rod is movably connected to the inner wall of the top of the fixed box through a bearing, the moving block is in threaded connection with the screw rod, the guide seats are installed at two ends of the moving block, the guide seats are embedded on the inner wall of the fixed box, the supporting seat is installed on the moving block, and the supporting seat penetrates out.

Further, one section that the supporting seat is located the fixed box outside is installed the drainage cover, the drainage cover shelters from the fixed box, the drainage cover includes fixed station, lower fixed station and drainage top facing, go up the fixed station be located down the fixed station directly over and with fixed station parallel arrangement down, go up the fixed station and pass through the drainage top facing with lower fixed station and connect.

Further, arrange sediment subassembly including arranging sediment push rod, toper row sediment piece and connecting rod, arrange the up end of sediment push rod and install toper row sediment piece, the toper is arranged the sediment piece and is located row sediment mouth under, arrange the lower terminal surface of sediment push rod and install the connecting rod, connecting rod threaded connection is on the supporting seat, set up the inner thread groove with the connecting rod adaptation on the supporting seat.

Further, the supporting component comprises a supporting plate, a connecting strip A, a connecting strip B, a connecting strip C and a connecting strip D, wherein the connecting strip A, the connecting strip B, the connecting strip C and the connecting strip D are respectively installed on four end faces of the supporting plate, and the supporting plate is fixed on the supporting legs through the connecting strip A, the connecting strip B, the connecting strip C and the connecting strip D.

Furthermore, a guide groove for the guide seat to vertically move is formed in the inner wall of the fixed box, and the moving block is driven to move in the guide groove under the guide effect of the guide seat in a mode that the driving motor drives the screw to rotate.

Furthermore, a square through groove matched with the supporting seat is formed in the upper fixing table, and the supporting seat penetrates through the square through groove and is in threaded connection with the connecting rod through an inner thread groove.

Furthermore, the size of the lower end face of the conical slag discharging block is the same as that of the slag discharging push rod, and the slag discharging push rod is matched with the slag discharging port.

According to another aspect of the invention, an implementation method of a slag discharging mechanism for an HMC pulse stand-alone dust collector is provided, and comprises the following steps:

s1: the driving motor is started and drives the screw rod to rotate, and the screw rod can drive the moving block to vertically move upwards under the guiding action of the guide seat in the rotating process so as to enable the support seat and the slag discharging assembly to move upwards along with the guide seat;

s2: in the upward movement process of the slag discharging assembly, after a blockage at the slag discharging opening is pushed into the ash hopper through the conical slag discharging block, the driving motor is started and drives the screw rod to rotate reversely, and the screw rod can drive the moving block to vertically move downwards under the guiding action of the guide seat in the reverse rotation process so as to enable the support seat and the slag discharging assembly to move downwards until the conical slag discharging block leaves the slag discharging opening;

s3: because slag discharging opening no longer has the plug to block up, consequently the lime-ash accessible slag discharging opening discharge in the ash bucket to on dropping to the drainage mat facing, in the drainage effect whereabouts of drainage mat facing gets into the collection sediment storehouse, after arranging the sediment, will collect the sediment storehouse and take out and carry out subsequent processing to the lime-ash from supporting component can.

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

the invention relates to a slag discharging mechanism for an HMC pulse single-machine dust collector and an implementation method thereof.A driving motor is started and drives a screw rod to rotate, the screw rod can drive a moving block to vertically move upwards under the guiding action of a guide seat in the rotating process so as to enable a supporting seat and a slag discharging component to also move upwards along with the guide seat, the slag discharging component pushes a blockage at a slag discharging opening into an ash bucket through a conical slag discharging block in the upwards moving process, the driving motor is started and drives the screw rod to reversely rotate, the screw rod can drive the moving block to vertically move downwards under the guiding action of the guide seat in the reversely rotating process so as to enable the supporting seat and the slag discharging component to also move downwards along with the conical slag discharging block until the conical slag discharging block leaves the slag discharging opening, and as no blockage exists at the slag discharging opening, ash in the ash bucket can be discharged through the slag discharging opening and fall onto a drainage cover surface and then fall into a slag collecting bin under the drainage action, after the slag discharging is finished, the slag collecting bin is taken out of the supporting component and ash slag is subjected to subsequent treatment, and a slag discharging mechanism can disperse the blockage at the slag discharging port and discharge the blockage to the slag collecting bin from the slag discharging port, so that the problem that the slag discharging port of the traditional HMC pulse single-machine dust collector is easy to block and cannot discharge slag can be effectively solved, the smooth proceeding of slag discharging work of the HMC pulse single-machine dust collector can be effectively ensured, the slag discharging speed is high, and the slag discharging efficiency is greatly improved.

Drawings

FIG. 1 is a schematic diagram of a slag discharge mechanism for an HMC pulse stand-alone dust collector according to the present invention;

FIG. 2 is a schematic view of the slag removal mechanism with the attached flow-inducing hood of the present invention;

FIG. 3 is a cross-sectional view of the slag removing mechanism with the attached flow-inducing hood of the present invention;

FIG. 4 is a schematic view of the slag removal mechanism of the present invention without the hood;

FIG. 5 is a cross-sectional view of the slag removal mechanism of the present invention without the hood;

FIG. 6 is a cross-sectional exploded view of the slag extractor mechanism of the present invention without the hood;

FIG. 7 is a schematic view of the slag discharge assembly of the present invention;

FIG. 8 is a schematic view of a support assembly of the present invention;

FIG. 9 is an exploded view of the support assembly of the present invention;

FIG. 10 is a schematic view of a drainage mask of the present invention;

FIG. 11 is a cross-sectional view of a drainage mask of the present invention.

In the figure: 1. a dust remover; 11. an air inlet; 12. an exhaust port; 2. a support leg; 21. a support rod A; 22. a support bar B; 3. an ash hopper; 31. a slag discharge port; 4. a slag discharge mechanism; 41. a fixed box; 411. a guide groove; 42. a drive motor; 43. a screw; 44. a moving block; 45. a guide seat; 46. a supporting seat; 461. an internal thread groove; 47. a slag discharge assembly; 471. a slag discharge push rod; 472. conical slag discharging blocks; 473. a connecting rod; 5. a support assembly; 51. a support plate; 52. a connecting strip A; 53. a connecting strip B; 54. a connecting strip C; 55. a connecting strip D; 6. a slag collecting bin; 7. a drainage cover; 71. an upper fixed table; 711. a square through groove; 72. a lower fixed table; 73. and (6) draining cover surfaces.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a deslagging mechanism for a HMC pulse stand-alone dust collector comprises a dust collector 1, wherein an air inlet 11 and an air outlet 12 are arranged on the dust collector 1, the air inlet 11 is arranged at the lower end of the dust collector 1, the air outlet 12 is arranged at the upper end of the dust collector 1, dust-containing gas enters the dust collector 1 from the air inlet 11 at the lower end, is dedusted by a filter bag and is discharged from the air outlet 12 at the upper end, support legs 2 are arranged in parallel on the lower surface of the dust collector 1, a dust hopper 3 is also arranged at the lower end of the dust collector 1, the dust hopper 3 is arranged at the inner sides of the support legs 2 arranged in parallel, a deslagging port 31 is arranged on the dust hopper 3, ash in the dust hopper 3 can be discharged from the deslagging port 31, a deslagging mechanism 4 is arranged below the deslagging port 31, blockages at the deslagging port 31 can be dispersed and discharged from the deslagging port 31 to a deslagging bin 6 through the deslagging mechanism 4, and the deslagging port 31 of the conventional HMC pulse stand-alone dust collector can be effectively solved, can effectively guarantee going on smoothly of sediment work of HMC pulse unit dust collector, it is fast to make to arrange the sediment, the efficiency of arranging the sediment is greatly improved, sediment discharge mechanism 4 passes through bracing piece A21 and bracing piece B22 and fixes on stabilizer blade 2, the lower extreme of stabilizer blade 2 is provided with supporting component 5, placed album sediment storehouse 6 on the supporting component 5, support album sediment storehouse 6 through supporting component 5, the lime-ash in the ash bucket 3 is discharged through row's cinder notch 31, and fall to on drainage top facing 73, fall into in album sediment storehouse 6 under the drainage effect of drainage top facing 73, after arranging the sediment, it can to take out and carry out subsequent processing to the lime-ash from supporting component 5 with album sediment storehouse 6, it is located sediment discharge mechanism 4 under to collect sediment storehouse 6.

Referring to fig. 2-6, the slag discharging mechanism 4 includes a fixed box 41, a driving motor 42, a screw 43, a moving block 44, a guide seat 45, a support seat 46 and a slag discharging assembly 47, the fixed box 41 is installed on a support rod a21 and a support rod B22, the driving motor 42 is installed on the inner wall of the fixed box 41, the screw 43 is installed on the output shaft of the driving motor 42 through a coupler, the upper end of the screw 43 is movably connected on the inner wall of the top of the fixed box 41 through a bearing, the moving block 44 is connected with the screw 43 through a thread, the guide seats 45 are installed at both ends of the moving block 44, the guide seat 45 is embedded on the inner wall of the fixed box 41, a guide groove 411 for the guide seat 45 to vertically move is opened on the inner wall of the fixed box 41, the moving block 44 drives the moving block 44 to move in the guide groove 411 under the guiding action of the, the supporting seat 46 penetrates through the fixed box 41 and is provided with a slag discharging assembly 47, the driving motor 42 is started and drives the screw rod 43 to rotate, and the screw rod 43 can drive the moving block 44 to vertically move under the guiding action of the guiding seat 45 in the rotating process so as to enable the supporting seat 46 and the slag discharging assembly 47 to move along with the screw rod 43.

Referring to fig. 7, the slag discharging assembly 47 includes a slag discharging push rod 471, a tapered slag discharging block 472 and a connecting rod 473, the tapered slag discharging block 472 is mounted on the upper end surface of the slag discharging push rod 471, the tapered slag discharging block 472 is located right below the slag discharging port 31, the size of the lower end surface of the tapered slag discharging block 472 is the same as that of the slag discharging push rod 471, the slag discharging push rod 471 is adapted to the slag discharging port 31, so that during the upward movement of the slag discharging assembly 47, the blockage at the slag discharging port 31 can be pushed into the ash bucket 3 through the tapered slag discharging block 472 and scattered at the slag discharging port 31, the connecting rod 473 is mounted on the lower end surface of the slag discharging push rod 471, the connecting rod 473 is threadedly connected to the supporting seat 46, the supporting seat 46 is provided with an internal thread groove 461 adapted to the connecting rod 473, the driving motor 42 is started and drives the screw 43 to rotate, the screw 43 can drive the moving block 44 to vertically move upward under the guiding action of the guiding seat 45 during the rotation, so, in the upward moving process of the slag discharging component 47, after the blockage at the slag discharging port 31 is pushed into the ash bucket 3 through the conical slag discharging block 472, the driving motor 42 is started and drives the screw 43 to rotate reversely, the screw 43 can drive the moving block 44 to vertically move downwards under the guiding action of the guide seat 45 in the process of rotating reversely, so that the support seat 46 and the slag discharging component 47 also move downwards along with the blockage, until the conical slag discharging block 472 leaves the slag discharging port 31, and because the blockage at the slag discharging port 31 is not blocked any more, ash slag in the ash bucket 3 can be discharged through the slag discharging port 31 and fall onto the drainage cover surface 73, and fall into the slag collecting bin 6 under the drainage action of the drainage cover surface 73, and after slag discharging is finished, the slag collecting bin 6 is taken out from the support component 5 and is subjected to subsequent treatment.

Referring to fig. 8-9, the supporting assembly 5 includes a supporting plate 51, a connecting bar a52, a connecting bar B53, a connecting bar C54 and a connecting bar D55, the four end surfaces of the supporting plate 51 are respectively provided with the connecting bar a52, the connecting bar B53, the connecting bar C54 and the connecting bar D55, the supporting plate 51 is fixed on the supporting legs 2 through the connecting bar a52, the connecting bar B53, the connecting bar C54 and the connecting bar D55, the supporting assembly 5 composed of the supporting plate 51, the connecting bar a52, the connecting bar B53, the connecting bar C54 and the connecting bar D55 supports the slag collecting bin 6, and after slag discharge is completed, the slag collecting bin 6 is taken out from the supporting assembly 5 and subjected to subsequent treatment on ash slag, so that the slag collecting bin 6 is convenient to take and place, and convenient to use can be greatly improved.

Referring to fig. 10-11, a section of the supporting seat 46 located outside the fixed box 41 is provided with a flow guide cover 7, the flow guide cover 7 shields the fixed box 41, the flow guide cover 7 comprises an upper fixed table 71, a lower fixed table 72 and a flow guide cover surface 73, the upper fixed table 71 is located right above the lower fixed table 72 and is arranged in parallel with the lower fixed table 72, the upper fixed table 71 and the lower fixed table 72 are connected through the flow guide cover surface 73, a square through groove 711 matched with the supporting seat 46 is formed in the upper fixed table 71, the supporting seat 46 penetrates through the square through groove 711 and is in threaded connection with a connecting rod 473 through an inner threaded groove 461, so that the slag discharge assembly 47 is convenient to mount or dismount, the use is convenient, and the later maintenance is convenient.

In order to better show the implementation flow of the slag discharging mechanism for the HMC pulse stand-alone dust collector, this embodiment now proposes an implementation method of the slag discharging mechanism for the HMC pulse stand-alone dust collector, including the following steps:

s1: the driving motor 42 is started and drives the screw rod 43 to rotate, and the screw rod 43 can drive the moving block 44 to vertically move upwards under the guiding action of the guide seat 45 in the rotating process so as to enable the support seat 46 and the slag discharging assembly 47 to move upwards along with the screw rod;

s2: in the upward moving process of the slag discharging assembly 47, after the blockage at the slag discharging port 31 is pushed into the ash bucket 3 through the conical slag discharging block 472, the driving motor 42 is started and drives the screw 43 to rotate reversely, and the screw 43 can drive the moving block 44 to vertically move downwards under the guiding action of the guide seat 45 in the process of rotating reversely, so that the support seat 46 and the slag discharging assembly 47 also move downwards along with the screw until the conical slag discharging block 472 leaves the slag discharging port 31;

s3: because there is no longer the jam of plug in the department of row's cinder notch 31, consequently the lime-ash accessible row cinder notch 31 in the ash bucket 3 discharges to on the drainage mat facing 73, in the drainage effect of drainage mat facing 73 drops into collection sediment storehouse 6, after the row sediment, take out collection sediment storehouse 6 from supporting component 5 and carry out subsequent processing to the lime-ash can.

The working principle is as follows: the driving motor 42 is started and drives the screw rod 43 to rotate, the screw rod 43 can drive the moving block 44 to vertically move upwards under the guiding action of the guiding seat 45 in the rotating process so as to enable the supporting seat 46 and the slag discharging component 47 to move upwards, the slag discharging component 47 can drive the moving block 44 to vertically move downwards under the guiding action of the guiding seat 45 in the process of moving upwards through the conical slag discharging block 472 so as to enable the supporting seat 46 and the slag discharging component 47 to also move downwards along with the conical slag discharging block 472 after the conical slag discharging block 472 is pushed into the slag discharging port 31 in the process of rotating in the reverse direction, and the slag in the ash bucket 3 can be discharged through the slag discharging port 31 and fall onto the drainage cover surface 73 and fall into the slag collecting bin 6 under the drainage action of the drainage cover surface 73, after the slag discharging is finished, the slag collecting bin 6 is taken out from the supporting component 5 and ash slag is subjected to subsequent treatment, a blocking object at the slag discharging port 31 can be dispersed and discharged to the slag collecting bin 6 from the slag discharging port 31 through the slag discharging mechanism 4, the problem that the slag discharging port 31 of the traditional HMC pulse single-machine dust collector is easy to block and cannot discharge slag can be effectively solved, the smooth proceeding of slag discharging work of the HMC pulse single-machine dust collector can be effectively guaranteed, the slag discharging speed is high, and the slag discharging efficiency is greatly improved.

In conclusion, the slag discharging mechanism for the HMC pulse stand-alone dust collector and the implementation method thereof of the present invention, the driving motor 42 is started and drives the screw rod 43 to rotate, the screw rod 43 can drive the moving block 44 to move up vertically under the guiding action of the guiding seat 45 in the rotating process so as to move the supporting seat 46 and the slag discharging component 47 up, the slag discharging component 47 pushes the blockage at the slag discharging port 31 into the ash bucket 3 through the tapered slag discharging block 472 in the moving up process, the driving motor 42 is started and drives the screw rod 43 to rotate reversely, the screw rod 43 can drive the moving block 44 to move down vertically under the guiding action of the guiding seat 45 in the reversely rotating process so as to move the supporting seat 46 and the slag discharging component 47 down, until the tapered slag discharging block 472 leaves the slag discharging port 31, and as there is no longer blockage of the blockage at the slag discharging port 31, the ash residue in the ash bucket 3 can be discharged through the slag discharging port 31, and fall to drainage top facing 73, fall into collection sediment storehouse 6 in drainage effect of drainage top facing 73, after arranging the sediment, will collect sediment storehouse 6 from supporting component 5 take out and carry out subsequent treatment to the lime-ash can, can disperse the plug of arranging slag hole 31 department and discharge to collection sediment storehouse 6 from arranging slag hole 31 department through slag removal mechanism 4, can effectively solve traditional HMC pulse unit dust collector's row slag hole 31 and easily block up and can't arrange the sediment, can effectively guarantee going on smoothly of arranging the sediment work of HMC pulse unit dust collector, make row's sediment fast, improved the efficiency of arranging the sediment greatly.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (9)

1. The utility model provides a slag discharging mechanism for HMC pulse stand-alone dust collector, a serial communication port, including dust remover (1), be provided with air inlet (11) and gas vent (12) on dust remover (1), air inlet (11) are located the lower extreme of dust remover (1), gas vent (12) are located the upper end of dust remover (1), the under surface mounting of dust remover (1) has parallel arrangement's stabilizer blade (2), the lower extreme of dust remover (1) still is provided with ash bucket (3), ash bucket (3) are located the inboard of parallel arrangement's stabilizer blade (2), be provided with slag discharging opening (31) on ash bucket (3), the below of slag discharging opening (31) is provided with slag discharging mechanism (4), slag discharging mechanism (4) are fixed on stabilizer blade (2) through bracing piece A (21) and bracing piece B (22), the lower extreme of stabilizer blade (2) is provided with supporting component (5), a slag collecting bin (6) is placed on the supporting component (5), and the slag collecting bin (6) is located under the slag discharging mechanism (4).

2. The slag removing mechanism for the HMC pulse stand-alone dust collector of claim 1, wherein the slag removing mechanism (4) comprises a fixed box (41), a driving motor (42), a screw rod (43), a moving block (44), a guide seat (45), a support seat (46) and a slag removing component (47), the fixed box (41) is installed on a support rod A (21) and a support rod B (22), the driving motor (42) is installed on the inner wall of the fixed box (41), the screw rod (43) is installed on the output shaft of the driving motor (42) through a coupling, the upper end of the screw rod (43) is movably connected on the inner wall of the top of the fixed box (41) through a bearing, the moving block (44) is connected with the screw rod (43) through threads, the guide seats (45) are installed on both ends of the moving block (44), and the guide seats (45) are embedded on the inner wall of the fixed box (41), and a supporting seat (46) is arranged on the moving block (44), and the supporting seat (46) penetrates out of the fixed box (41) to be provided with a slag discharging assembly (47).

3. The slag discharging mechanism for the HMC pulse stand-alone dust collector is characterized in that a section, located outside the fixed box (41), of the supporting seat (46) is provided with a drainage cover (7), the drainage cover (7) covers the fixed box (41), the drainage cover (7) comprises an upper fixed table (71), a lower fixed table (72) and a drainage cover surface (73), the upper fixed table (71) is located right above the lower fixed table (72) and is arranged in parallel with the lower fixed table (72), and the upper fixed table (71) and the lower fixed table (72) are connected through the drainage cover surface (73).

4. The slag discharging mechanism for the HMC pulse stand-alone dust collector of claim 2, wherein the slag discharging assembly (47) comprises a slag discharging push rod (471), a tapered slag discharging block (472) and a connecting rod (473), the tapered slag discharging block (472) is mounted on the upper end surface of the slag discharging push rod (471), the tapered slag discharging block (472) is located right below the slag discharging port (31), the connecting rod (473) is mounted on the lower end surface of the slag discharging push rod (471), the connecting rod (473) is in threaded connection with the supporting seat (46), and an inner threaded groove (461) matched with the connecting rod (473) is formed in the supporting seat (46).

5. The slag discharging mechanism for the HMC pulse stand-alone dust collector is characterized in that the supporting component (5) comprises a supporting plate (51), a connecting strip A (52), a connecting strip B (53), a connecting strip C (54) and a connecting strip D (55), the connecting strip A (52), the connecting strip B (53), the connecting strip C (54) and the connecting strip D (55) are respectively installed on four end faces of the supporting plate (51), and the supporting plate (51) is fixed on the supporting leg (2) through the connecting strip A (52), the connecting strip B (53), the connecting strip C (54) and the connecting strip D (55).

6. The slag discharging mechanism for the HMC pulse stand-alone dust collector as claimed in claim 2, wherein a guide groove (411) for a guide seat (45) to vertically move is formed in an inner wall of the fixed box (41), and the moving block (44) is driven by the driving motor (42) to drive the screw rod (43) to rotate so as to drive the moving block (44) to move in the guide groove (411) under the guiding action of the guide seat (45).

7. The slag discharging mechanism for the HMC pulse stand-alone dust collector of claim 3, wherein the upper fixing table (71) is provided with a square through groove (711) adapted to the supporting seat (46), and the supporting seat (46) passes through the square through groove (711) and is in threaded connection with the connecting rod (473) through the internal thread groove (461).

8. The deslagging mechanism for the HMC pulse stand-alone dust collector disclosed in claim 4, wherein the size of the lower end surface of the conical deslagging block (472) is the same as that of a deslagging push rod (471), and the deslagging push rod (471) is matched with the deslagging port (31).

9. The implementation method of the slag discharging mechanism for the HMC pulse stand-alone dust collector disclosed by any one of claims 1 to 8 is characterized by comprising the following steps of:

s1: the driving motor (42) is started and drives the screw rod (43) to rotate, and the screw rod (43) can drive the moving block (44) to vertically move upwards under the guiding action of the guide seat (45) in the rotating process so as to enable the support seat (46) and the slag discharging assembly (47) to move upwards along with the guide seat;

s2: in the upward moving process of the slag discharging assembly (47), after a blockage at the slag discharging port (31) is jacked into the ash bucket (3) through the conical slag discharging block (472), the driving motor (42) is started and drives the screw rod (43) to rotate reversely, and the screw rod (43) can drive the moving block (44) to vertically move downwards under the guiding action of the guide seat (45) in the reverse rotating process so as to enable the supporting seat (46) and the slag discharging assembly (47) to move downwards along with the screw rod (43) until the conical slag discharging block (472) leaves the slag discharging port (31);

s3: because there is no longer the jam of plug in slag discharge mouth (31) department, consequently the lime-ash accessible slag discharge mouth (31) in ash bucket (3) is discharged to on drainage mat coat (73), in the drainage effect whereabouts of drainage mat coat (73) gets into collection sediment storehouse (6), after the row sediment, take out collection sediment storehouse (6) from supporting component (5) and carry out subsequent processing to the lime-ash can.

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