DUST REMOVAL FILLER, FOULING COLLECTION PAN AND GAS CLEANING DEVICE

Abstract

A gas purification system includes a dust removal filler, a fouling collection pan and a gas purification device. The dust removal filler has a plurality of rows of channels, each channel extending obliquely with respect to a vertical direction to form a windward surface, and a leeward surface, and a waveform plate. The peak portion of the waveform plate is attached to the leeward surface of the obliquely prismatic channel. During operation, dust adheres to a concave portion of a lower surface of the waveform plate and accumulates to form dust aggregates. When the gravity of the dust aggregates is greater than the adhesion force, the dust aggregates fall onto the windward surface of the channels and slide off from the windward surface of the channels.

Claims

1. A dust removal filler (6), comprising: a plurality of rows of channels (61), each channel (61) extending obliquely with respect to a vertical direction to form a windward surface (611) and a leeward surface (612); and a waveform plate (62), the peak portion of the waveform plate (62) is attached to the leeward surface (612) of the channel (61), during operation; dust adheres to a concave portion of a lower surface of the waveform plate (62) under the action of Van Der Waals force; dust accumulates under the action of Coulomb force to form dust aggregates; when the gravity of the dust aggregates is greater than the adhesion force, the dust aggregates fall onto the windward surface (611) of the channels (61); and the aggregates slide off from the windward surface (611) of the channels (61).

2. The dust removal filler (6) according to claim 1, wherein each channel (61) is obliquely prismatic-shaped and has a rectangular cross-section, one pair of opposite sides extending obliquely relative to the vertical direction to form the windward surface (611) and the leeward surface (612), and the other pair of opposite sides extending along the vertical direction, the obliquely prismatic channels (61) in two adjacent rows are inclined in opposite directions.

3. The dust removal filler (6) according to claim 2, wherein each row of obliquely prismatic channels (61) is formed by a rectangular-wave plate (63) and a partition plate (64) to define flow channels therebetween.

4. The dust removal filler (6) according to claim 3, wherein opening directions of two adjacent rectangular-wave plates (63) are opposite.

5. The dust removal filler (6) according to claim 1, wherein the inclination angle of the obliquely prismatic channel (61) is greater than the angle of repose of the intercepted dust.

6. A gas purification device, comprising: a body including a housing (5), an upper head (4), and a lower head (7); a plurality of fouling collection pans (3) arranged in the upper head (4) and the housing (5); and one or more layers of dust removal fillers (6) according to claim 1, each layer of dust removal fillers (6) is disposed between two adjacent fouling collection pans (3).

7. A fouling collection pan (3), comprising: a column tray (31); and at least one fouling collection device (300) arranged on the column tray (31), each fouling collection device (300) includes a gas collection cartridge (310) and a baffle plate (311) arranged on the outer wall of the gas collection cartridge (310); the baffle plate (311) is formed by multi-layer conical baffles, the conical baffle is composed of a conical plate (3111) and a waveform plate (3112); during operation; dust adheres to the concave portion of the lower surface of the waveform plate (3112) under the action of Van Der Waals force; dust accumulates under the action of Coulomb force to form dust aggregates; when the gravity of the dust aggregate is greater than the adhesion force, the dust aggregate falls onto the upper surface of the conical plate (3111) below, or directly falls onto the column tray (31); and the aggregate slide from the upper surface of the conical plate (3111) onto the column tray (31).

8. The fouling collection pan (3) according to claim 7, wherein the gas collection cartridge (310) is a vertical cylindrical structure, the top end of the gas collection cartridge (310) is closed, the lower end thereof is open, the lower end of the gas collection cartridge (310) passes through the column tray (31) and is connected with the column tray (31), and the outer wall of the gas collection cartridge (310) is provided with a plurality of ventilation holes (3101).

9. The fouling collection pan (3) according to claim 8, wherein the lower end of the gas collection cartridge (310) vertically passes through the column tray (31) and is connected with the column tray (31), and the ventilation hole (3101) is arranged on the cartridge wall between two adjacent layers of conical baffles.

10. The fouling collection pan (3) according to claim 7, wherein the column tray (31) is provided with a plurality of fouling collection devices (300), and the plurality of fouling collection devices (300) are evenly arranged on the column tray (31).

11. A gas purification device, comprising an upper head (4), a lower head (7) and a housing (5), at least one said fouling collection pan (3) according to claim 7, is arranged inside of the gas purification device.

12. The gas purification device according to claim 11, further comprising one or more layers of dust removal fillers (6), the gas purification device is provided with multi-layer fouling collection pans (3), and each layer of dust removal filler (6) is arranged between two adjacent fouling collection pans (3).

13. The gas purification device according to claim 11, further comprising one or more protective agent beds (10), and the protective agent beds (10) are arranged under the fouling collection pan (3).

14. The gas purification device according to claim 13, wherein the protective agent bed (10) is filled with a bird-nest protective agent, and the bird-nest protective agent includes a cartridge and a plurality of ribs, the plurality of ribs intersect each other to form a grid, and form an acute angle at the point of intersections.

15. The gas purification device according to claim 14, wherein when multi-layer dust removal fillers (6) are provided, the wave amplitude and wavelength of the waveform plates (62) of the multi-layer dust removal fillers (6) gradually decrease along the gas flow direction.

16. A fouling collection pan (3) comprising: a column tray (31); and a fouling collection device (300) arranged on the column tray (31), the fouling collection device (300) includes a filter body (305), a baffle separation body (304) and a cover plate (303); the filter body (305) is a sleeve annular columnar structure defining a fouling collection device axis; the baffle separation body (304) is a columnar structure of annular folded plates extending around the fouling collection device axis, formed of multi-layer annular folded plates, and the cross section of the annular folded plates is an inverted V shape, thereby forming an inverted V-shaped annular folded plate extending around the fouling collection device axis, the baffle separation body (304) is sleeved outside of the filter body (305); the cover plate (303) is located above the baffle separation body (304) and the filter body (305) and covers the baffle separation body (304) and the filter body (305), the top end of the baffle separation body (304) is connected with the cover plate (303); during operation; dust adheres to the apex of inverted V-shape of the annular folded plate under the action of Van Der Waals force; dust accumulates under the action of Coulomb force to form dust aggregates; when the gravity of the dust aggregates is greater than the adhesion force, the dust aggregates falls onto the upper surface of the annular folded plate below, or directly falls onto the column tray (31); and the aggregates slides off the upper surface of the annular folded plate onto the column tray (31).

17. The fouling collection pan (3) according to claim 16, wherein the lower end of the filter body (305) passes through the column tray (31), and the filter body (305) includes an inner cylinder (307), an outer cylinder (308) and a fouling collection filling material (306) arranged in an annular space between the inner cylinder (307) and the outer cylinder (308).

18. A gas purification device, comprising an upper head (4), a lower head (7) and a housing (5), at least one said fouling collection pan (3) according to claim 16 is arranged inside of the gas purification device.

19. The gas purification device according to claim 18, further comprising one or more layers of dust removal fillers (6), and each layer of the dust removal filler (6) is arranged between two adjacent fouling collection pans (3).

20. The gas purification device according to claim 18, the gas purification device is provided with multi-layer fouling collection pans (3), a protective agent bed (10) or a dust removal filler (6) is arranged between the two adjacent layers of fouling collection pans (3), and the dust removal filler (6) is set above the protective agent bed (10), when three layers of fouling collection pans are installed, a first layer of fouling collection pan (3), a dust removal filler (6), a second layer of fouling collection pan (3), a protective agent bed (10) and a third layer of fouling collection pan (3) are in order according a gas flow direction.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0062] FIG. 1 is a structural schematic view of a gas purification device according to a first embodiment of the invention.

[0063] FIG. 2 is a structural schematic view of the dust removal filler of the gas purification device shown in FIG. 1.

[0064] FIG. 3 is a partially enlarged view of the dust removal filler shown in FIG. 2.

[0065] FIG. 4 is a partial structural schematic view of the obliquely prismatic channel of the dust removal filler, where the waveform plate is not shown.

[0066] FIG. 5 is a schematic view of a fouling collection pan according to a first embodiment of the invention.

[0067] FIG. 6 is a schematic view of the appearance and structure of the fouling collection pan shown in FIG. 5.

[0068] FIG. 7 is a schematic view of the flow field and flow state of the fouling collection pan shown in FIG. 5.

[0069] FIG. 8 is a structural schematic view of a fouling collection pan according to a second embodiment of the invention.

[0070] FIG. 9 is a schematic view of the appearance and structure of the fouling collection pan shown in FIG. 8.

[0071] FIG. 10 is a schematic view of the flow field and flow state of the fouling collection pan shown in FIG. 8.

[0072] FIG. 11 is a structural schematic view of a gas purification device according to a second embodiment of the invention.

[0073] FIG. 12 is a structural schematic view of a gas purification device according to a third embodiment of the invention.

[0074] FIG. 13 is a structural schematic view of a bird-nest filler.

DETAILED DESCRIPTION OF EMBODIMENTS

[0075] The specific situation of the invention will be further described below in conjunction with the accompanying drawings and specific embodiments, but is not limited to the following embodiments.

[0076] In the description of the invention, it should be noted that the orientation or positional relationship indicated by the terms “upper”, “lower”, “inner”, “outer”, “top”, “bottom” etc. is based on the orientation or positional relationship, is only for the convenience of describing the invention and simplifying the description, but does not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as a limitation of the invention. In addition, the terms “first” and “second” are used for descriptive purposes only, and should not be understood as indicating or implying relative importance.

[0077] In the description of the invention, it should be noted that, unless otherwise clearly specified and defined, the terms “provided with”, “arranged at”, “connected with”, “connected to”, “installed to”, etc. should be understood in a broad sense, for example, they can be a fixed connection, a detachable connection, or an integral connection; they can be a direct connection, or an indirect connection through an intermediate media, or an internal communication between two components. Those of ordinary skill in the art can understand the specific meanings of the above terms in the invention in specific situations.

[0078] FIG. 1 is a structural schematic view of a gas purification device according to a first embodiment of the invention. As shown in FIG. 1, the invention provides a gas purification device, which includes an upper head 4, a housing 5 and a lower head 7. The upper head is provided with a gas inlet 1, below which an inlet diffuser 2 may also be arranged. The lower head is provided with a gas outlet 9, above which an outlet collector 8 is arranged. A fouling collection pan 3 is arranged inside the gas purification device, and the fouling collection pan 3 is arranged in the upper head 4 and/or in the housing 5. Preferably, the uppermost fouling collection pan 3 is arranged in the upper head 4, and the dimension of the fouling collection pan 3 arranged in the upper head 4 is larger than the dimension of other fouling collection pans 3 arranged in the housing. A dust removal filler 6 is arranged below the fouling collection pan 3. Preferably, the dust-removing filler is arranged between two layers of fouling collection pans 3.

[0079] FIG. 2 is a structural schematic view of the dust removal filler of the gas purification device shown in FIG. 1. FIG. 3 is a partially enlarged view of the dust removal filler shown in FIG. 2. FIG. 4 is a partial structural schematic view of the obliquely prismatic channel of the dust removal filler, wherein the waveform plate is not shown. As shown in FIG. 2 to FIG. 4, the dust removal filler 6 according to the specific embodiment of the invention includes multiple rows of channels 61, and each channel 61 extends obliquely relative to a vertical direction to form a windward surface 611 and a leeward surface 612. In the illustrated embodiment, each channel 61 is obliquely prismatic shaped, and the cross-section thereof is rectangular. One pair of opposite sides are inclined relative to the vertical direction to form the windward surface 611 and the leeward surface 612, and the other pair of opposite sides extend along the vertical direction. It should be understood that the channel 61 may adopt other shapes as long as the channel 61 extends obliquely relative to the vertical direction to form a windward surface and a leeward surface. According to a preferred embodiment, the inclination directions of the obliquely prismatic channels 61 in two adjacent rows are opposite (as shown in FIG. 4). The peak portions of the waveform plate 62 are attached to the leeward surface 612 of the obliquely prismatic channel 61. The peak portions of the waveform plate 62 can be attached to the leeward surface 612 of the obliquely prismatic channel 61 in any suitable manner, including but not limited to by welding.

[0080] When the gas flows from top to bottom, it only flows through the area between the waveform plate 62 and the windward surface 611, and does not flow into the area between the waveform plate 62 and the leeward surface 612. The gas entrained with fine dust enters the dust removal filler 6. When the gas flows through the dust removal filler 6, under the action of the waveform plate 62, a vortex is generated, which provides time and close distance for the adhesion of ultrafine dust and aggregation between dust. The ultrafine dust adheres to the waveform plate 62 under the action of Van Der Waals force, and the ultrafine dust accumulates at the concave portion of the lower surface of the waveform plate 62 under the action of Coulomb force to form aggregates (ash clusters). When the gravity of the aggregates (ash clusters) is greater than the adhesion force, it falls onto the windward surface 611 of the obliquely prismatic channel 61 of the dust removal filler 6. The windward surface 611 has a certain inclination angle, and the inclination angle is greater than the angle of sliding repose of the dust, and the ash clusters will slide off.

[0081] As shown in FIG. 2, in one or more embodiments of the invention, each row of obliquely prismatic channels 61 is formed by a rectangular-wave plate 63 and a partition plate 64 to define flow channels therebetween. In one or more exemplary embodiments of the invention, both the rectangular-wave plate 63 and the waveform plate 62 are made of metal plates by stamping, so as to be able to apply to the working environment of high temperature and high pressure. In one or more exemplary embodiments of the invention, the opening directions of two adjacent rectangular-wave plates 63 are opposite. It should be understood that the invention is not limited thereto, and those skilled in the art can select the material and manufacturing method of the obliquely prismatic channel according to actual needs, for example, non-metallic materials such as plastics, or other metal materials with good ductility such as aluminum, etc. are used under normal temperature and normal pressure conditions. Forming methods can utilize molding. The rectangular-wave plate 63 and the waveform plate 62 can be connected in any suitable way, including but not limited to by welding and the like.

[0082] Further, in one or more exemplary embodiments of the invention, the inclination angle of the obliquely prismatic channel 61 is greater than the angle of repose of the intercepted dust. The inclination angle of the obliquely prismatic channel 61 may be 15°-75°, preferably may be 30°-60°. The inclination angle of the obliquely prismatic channel 61 is defined as the included angle (acute angle) of the obliquely prismatic channel 61 relative to the horizontal plane. It should be understood that the invention is not limited thereto, and the inclination angle of the obliquely prismatic channel 61 can be set according to the angle of repose of the intercepted dust.

[0083] Further, in one or more exemplary embodiments of the invention, the width of the windward surface 611 and the leeward surface 612 is 2 mm-100 mm, preferably 5 mm-30 mm; the width of the sides extending along the vertical direction of the obliquely prismatic channel is 5 mm-200 mm, preferably 20 mm-80 mm. Further, in one or more exemplary embodiments of the invention, the wave amplitude of the waveform plate 62 is 1 mm-100 mm, preferably 3 mm-60 mm; the wavelength is 20 mm-300 mm, preferably 30 mm-220 mm; the distance from wave valley of the waveform plate 62 to the windward surface 611 of the adjacent obliquely prismatic channel is 2 mm-80 mm, preferably 5 mm-30 mm.

[0084] Further, when the multi-layer dust removal filler 6 is installed, the wave amplitude and wavelength of the waveform plates 62 of the multi-layer dust removal filler 6 gradually decrease along the flow direction of the gas material, so as to meet the requirement of gradual reduction of dust particle size.

[0085] FIG. 5 is a structural schematic view of a fouling collection pan according to a first embodiment of the invention. FIG. 6 is a schematic view of the appearance and structure of the fouling collection pan shown in FIG. 5. FIG. 7 is a schematic view of the flow field and flow state of the fouling collection pan shown in FIG. 5. As shown in FIG. 5-FIG. 7, the invention provides a fouling collection pan, which includes a column tray 31 and a fouling collection device 300 arranged on the column tray. The fouling collection device 300 includes a gas collection cartridge 310 and a baffle plate 311 arranged on the outer wall of the gas collection cartridge.

[0086] In the above fouling collection pan, the baffle plate 311 is formed by a multi-layer conical baffle, and the conical baffle is composed of a conical plate 3111 and a waveform plate 3112; wherein the waveform of the waveform plate 3112 is a sine curve or cosine curve, the amplitude is 1 mm-80 mm, preferably 3 mm-40 mm; the wavelength is 30 mm-400 mm, preferably 80 mm-150 mm. The peak portions of the waveform plate 3112 are attached to the lower surface of the tapered plate 3111. The waveform plate 3112 and the conical plate 3111 can be connected in any suitable way, including but not limited to by welding.

[0087] In the above fouling collection pan, the gas collection cartridge 310 is a vertical cylindrical structure. The top end of gas collection cartridge 310 is closed, and the lower end thereof is open. The lower end of gas collection cartridge 310 passes through the column tray 31 and is connected with the column tray 31. Preferably, the gas collection cartridge 310 vertically passes through the column tray 31, and the outer wall of gas collection cartridge 310 is provided with a plurality of ventilation holes 3101, which are used as gas feed ports. The opening positions of the ventilation holes 3101 can be specifically arranged on the cartridge wall between two adjacent layers of conical baffles. The gas collection cartridge 310 is used as a gas flow channel.

[0088] In the above fouling collection pan, the cone angle of the baffle plate 311 is 30°-175°, preferably 90°-110°; the distance between two adjacent layers of conical baffles is 1.2-5 times the amplitude of the waveform plate, preferably 1.5-3 times the amplitude of the waveform plate, more preferably 1.8-2.5 times the amplitude of the waveform plate. In the invention, the cone angle of the baffle plate 311 is defined as the apex angle of a isosceles triangle obtained by extending the cross-sectional profile of each baffle plate 311 in the cross-sectional view shown in FIG. 7, and the inclination angle of the baffle plate 311 is defined as the base angle of the isosceles triangle.

[0089] In the above fouling collection pan, the column tray 31 is provided with a plurality of fouling collection devices 300, and the specific number of fouling collection devices can be determined by those skilled in the art according to actual needs. When more than two fouling collection devices are arranged, a plurality of fouling collection devices are evenly arranged on the column tray, such as but not limited to: in square arrangement, in regular triangle arrangement, in circular arrangement, etc.

[0090] By means of the fouling collection pan, the gas flowing therethrough is blocked and limited to achieve a restricted even flow; when the gas flows through the conical baffle, a multi-layer wave-shaped gas flow line is formed, and the gas forms a vortex at the turning point, and the dust is separated from the flow line under the impact of the gas molecule and performs Brownian motion like gas molecules. Due to the low flow velocity and the molecular force (Van der Waals force) near the wall, the adhesion phenomenon occurs very easily between the powder particles and the conical baffle, thereby forming dust aggregates; with the accumulation of dust, the volume increases. When the gravity of the dust aggregate is greater than the adhesion force, the dust aggregate will peel off from the conical baffle and fall onto the next layer of conical baffle below, or will directly fall onto the column tray 31 if it is the lowest layer of conical baffles. The conical baffle is composed of a conical plate and a waveform plate, the upper surface of the conical plate is a smooth inclined plate, and the inclination angle thereof is greater than the angle of repose of the dust. With the accumulation of dust on the upper surface of the conical plate, when the gravity of the dust aggregate is greater than the sliding resistance, the dust aggregate will slide off along the surface of the conical plate and fall onto the column tray, thus completing the interception and storage of dust. The low flow velocity at the gas vortex facilitates the electrostatic force (Coulomb force) to play a role, and the dust will accumulate and agglomerate to form aggregates. When the dust aggregates are large enough, the thermophoretic force of the gas is not enough to suspend and entrain the dust particles, causing the deposition of dust particles.

[0091] FIG. 8 is a structural schematic view of a fouling collection pan according to a second embodiment of the invention. FIG. 9 is a schematic view of the appearance and structure of the fouling collection pan shown in FIG. 8. FIG. 10 is a schematic view of the flow field and flow state of the fouling collection pan shown in FIG. 8. As shown in FIG. 8-FIG. 10, the invention provides a fouling collection pan. The fouling collection pan 3 includes a column tray 31 and a plurality of fouling collection devices 30 arranged on the column tray. The plurality of fouling collection devices 30 are evenly arranged on the column tray 31, and specifically can be arranged in a square arrangement, in an equilateral triangle arrangement, or the like.

[0092] The fouling collection device 30 includes a cover plate 303, a baffle separation body 304 and a filter body 305 passing through the column tray; the cover plate 303 is located above the baffle separation body 304 and the filter body 305 and covers the baffle separation body 304 and the filter body 305, so as to ensure that the gas material enters the fouling collection device through the baffle separation body 304, the top end of the baffle separation body 304 is connected to the cover plate 303, and the bottom end of the baffle separation body 304 is fixed on the column tray 301; the baffle separation body 304 is coaxially sleeved outside of the filter body 305, and there is a certain distance between the baffle separation body 304 and the filter body 305, which annular space can be used to store the captured solid substance; that is, in the contact order of the gas material, the gas at first passes through the baffle separator 304, and then passes through the filter body 305.

[0093] The baffle separation body 304 is a columnar structure of annular folded plates, formed by stacking a plurality of inverted V-shaped annular folded plates, and the annular folded plates can be fixed by using, for example but not limited to, multiple columns or an annular frame (not shown). The cone angle of the inverted V-shaped annular folded plate is 15°-150°, preferably 30°-90°; the distance between two adjacent annular folded plates is 3 mm-80 mm, preferably 8 mm-28 mm. The inclination angle of the annular folded plate is greater than the angle of repose of the solid substance in the gas, doing so can accelerate sliding along the surface of the folded plates for particle aggregates of solid substance. In the invention, the cone angle of the annular folded plate is defined as the apex angle of the isosceles triangle obtained by extending the section profile of each annular folded plate in the cross-sectional view shown in FIG. 10, and the inclination angle of the annular folded plate is defined as the base angle of the isosceles triangle.

[0094] The filter body 305 is a sleeve annular columnar structure, the lower end of the filter body 305 passes through the column tray 31, and the filter body 305 includes an inner cylinder 307, an outer cylinder 308 and a fouling collection filling material 306 arranged in the annular space between the inner cylinder and the outer cylinder, the filter body 305 is annular columnar; the width between the inner cylinder 307 and the outer cylinder 308 is 10 mm-500 mm, preferably 100 mm-300 mm; further preferably the inner cylinder 307 and the outer cylinder 308 is of the same height, and are sleeved together and are made of screen; the inner cylinder 307 passes through the column tray 301 and is used as a gas channel; the annular columnar filter body has a suitable porosity.

[0095] There is a certain gap between the cover plate 303 and the upper end of the filter body 305, and this gap can be used as a gas flow channel after the filter body 305 is blocked. The height of the gap is 5 mm-200 mm, preferably 20 mm-120 mm. When sufficient solid substance is intercepted or even submerges the fouling collection device, the fouling collection pan loses the function of intercepting dust, but the space between the cover plate 303 and the upper end of the filter body 305 can still be used as a gas material channel, thereby not generating pressure drop and keeping the device running stably for a long period of time. Further, in one or more exemplary embodiments of the invention, the cover plate 303 may be in the shape of a cone, a truncated cone or a straw hat. It should be understood that the cover plate 303 shown in the drawings is a straw hat shape, but the invention is not limited thereto.

[0096] Further, in one or more exemplary embodiments of the invention, the dimension of the fouling collection pan 3 disposed in the upper head 4 is larger than the dimension of other fouling collection pans 3.

[0097] Further, in one or more exemplary embodiments of the invention, when the protective agent bed is multi-layered, the porosity of the multi-layer protective agent bed 6 gradually decreases in the gas material flow direction.

[0098] By means of the fouling collection pan, the gas flowing therethrough is blocked and limited to achieve a restricted even flow; when the gas flows through the inverted V-shaped annular folded plate, the gas forms a vortex at the turning point, and the dust is separated from the flow line under the impact of the gas molecule and performs Brownian motion like gas molecules. Due to the low flow velocity and the molecular force (Van Der Waals force) near the wall, the adhesion phenomenon occurs very easily between the powder particles and the annular folded plate, thereby forming dust aggregates; with the accumulation of dust, the volume increases. When the gravity of the dust aggregate is greater than the adhesion force, the dust aggregate will peel off from the annular folded plate and fall onto the next layer of annular folded plate below, or will directly fall onto the column tray 31 if it is the lowest layer of annular folded plates. The upper surface of the annular folded plate is a smooth inclined plate, and the inclination angle thereof is greater than the angle of repose of the dust. With the accumulation of dust on the upper surface of the annular folded plate, when the gravity of the dust aggregate is greater than the sliding resistance, the dust aggregate will slide off along the surface of the conical plate and fall onto the column tray, thus completing the interception and storage of dust. The low flow velocity at the gas vortex facilitates the electrostatic force (Coulomb force) to play a role, and the dust will accumulate and agglomerate to form aggregates. When the dust aggregates are large enough, the thermophoretic force of the gas is not enough to suspend and entrain the dust particles, causing the deposition of dust particles.

[0099] FIG. 11 is a structural schematic view of a gas purification device according to a second embodiment of the invention. As shown in FIG. 11, the invention provides the gas purification device of the second embodiment, the device includes an upper head 4, a housing 5 and a lower head 7; the upper head is provided with a gas inlet 1, below which an inlet diffuser 2 may also be arranged. The lower head is provided with a gas outlet 9, above which an outlet collector 8 is arranged; the interior of the device is provided with multi-layer fouling collection pans 3 as described above, a dust removal filler 6 and a protective agent bed 10, the dust removal filler 6 or the protective agent bed 10 is arranged between the two adjacent layers of fouling collection pans 3, and the dust removal filler 6 is arranged above the protective agent bed 10. Specifically, when three layers of fouling collection pans, the dust removal filler, and the protective agent bed are provided, a first layer of fouling collection pan, the dust removal filler, a second layer of fouling collection pan, the protective agent bed and a third layer of fouling collection pan are in order according a gas flow direction. The fouling collection pans 3 are arranged in the upper head 4 and/or in the housing 5, preferably arranged in the upper head 4, and the dimension of the fouling collection pan 3 arranged in the upper head 4 is larger than the dimension of other fouling collection pan(s) 3 arranged in the housing. The protective agent bed 10 is filled with bird-nest structure protective agent, as shown in FIG. 13, the bird-nest filler is composed of a cartridge and a plurality of ribs, the plurality of ribs intersect each other to form a grid, and form an acute angle at the point of intersections.

[0100] FIG. 12 is a structural schematic view of a gas purification device according to a third embodiment of the invention. FIG. 13 is a structural schematic view of a bird-nest filler. As shown in FIG. 12, the invention provides the gas purification device of the third embodiment, and said device comprises an upper head 4, a housing 5 and a lower head 7; the upper head is provided with a gas inlet 1, below which an inlet diffuser 2 may also be arranged. The lower head is provided with a gas outlet 9, above which an outlet collector 8 is arranged; the interior of the device is provided with fouling collection pans 3. The fouling collection pans 3 are arranged in the upper head 4 and/or in the housing 5, preferably arranged in the upper head 4, and the dimension of the fouling collection pan 3 arranged in the upper head 4 is larger than the dimension of other fouling collection pan(s) 3 arranged in the housing. A protective agent bed is arranged below the fouling collection pan 3, and it is further preferred that the protective agent bed 10 is disposed between two layers of fouling collection pans 3. The protective agent bed 10 is filled with bird-nest structure protective agent, as shown in FIG. 13, the bird-nest filler is composed of a cartridge and a plurality of ribs, the plurality of ribs intersect each other to form a grid, and form an acute angle at the point of intersections.

[0101] The dusty gas after being treated by the fouling collection pan and dust removal filler enters the protective agent bed, which has the function of “filtering”, can further intercept and store the solid substance in the gas. When the bird-nest structure protective agent bed is used, dust has bridging properties, and a bridging effect is formed at the acute angle formed by the intersection of the ribs of the bird-nest protective agent to realize the deposition of dust; as the operation cycle advances, the dust adheres and bridges under the action of Van Der Waals force, and accumulates under the action of Coulomb force; fine dust clusters grow up, and when the ash clusters fall off, they are pushed by the gas. A fouling collection pan is arranged under the bird-nest protective agent bed to provide a low flow velocity condition for the ash clusters, and to form a stagnant layer above the fouling collection pan, which is beneficial for the interception and storage of dust ash clusters, thereby realizing the separation of fine dust particles. Providing different specifications of bird-nest protective agent beds will deeply separate the ultrafine dust. The purified gas flows out from the outlet collector and gas outlet arranged on the lower head, and the dust removal and purification process of the gas is completed so far.

[0102] The preferred embodiments of the invention have been described in detail above with reference to the accompanying drawings, however, the invention is not limited thereto. Within the scope of the technical concept of the invention, various simple modifications can be made to the technical solution of the invention, including combinations of specific technical features in any suitable manner. In order to avoid unnecessary repetition, various possible combinations are not further described in the invention. However, these simple modifications and combinations should also be regarded as the content disclosed by the invention, and all belong to the protection scope of the invention.