阅读说明：本技术 一种基于物联网远程控制的高空气体净化处理设备 (High-altitude gas purification treatment equipment based on remote control of Internet of things ) 是由 郑海利 于 2021-08-22 设计创作，主要内容包括：本发明公开了一种基于物联网远程控制的高空气体净化处理设备,包括设备外壳、吸气设备、固定架和滑杆,所述设备外壳的内部固定安装有水箱,所述水箱的右侧固定安装有导水管,所述进水管的外部固定有加热包,所述吸气设备固定安装在设备外壳的内部,所述安装架和设备外壳的侧面均固定有加固环,所述滑杆固定在安装架的侧面,所述底部转轴下端与定位板相互连接。该基于物联网远程控制的高空气体净化处理设备,采用新型的结构设计,使得本装置内部设置有气体循环处理结构,使用较为节能,且该装置可以分步依次对气体进行净化处理,提高气体处理效果,同时该装置中设置有设备往复转动结构,提高装置处理气体的范围。(The invention discloses high-altitude gas purification treatment equipment based on Internet of things remote control, which comprises an equipment shell, air suction equipment, a fixing frame and a sliding rod, wherein a water tank is fixedly arranged inside the equipment shell, a water guide pipe is fixedly arranged on the right side of the water tank, a heating bag is fixed outside the water inlet pipe, the air suction equipment is fixedly arranged inside the equipment shell, reinforcing rings are fixed on the side surfaces of the mounting frame and the equipment shell, the sliding rod is fixed on the side surface of the mounting frame, and the lower end of a rotating shaft at the bottom is connected with the positioning plate. This gaseous purification treatment equipment in high altitude based on thing networking remote control adopts neotype structural design for this device is inside to be provided with gas circulation processing structure, uses comparatively energy-conservingly, and the device can step by step carry out purification treatment to gas in proper order, improves the gas treatment effect, is provided with the reciprocal rotating-structure of equipment among the device simultaneously, improves the gaseous scope of device processing.)

1. The utility model provides a high altitude gas purification treatment facility based on thing networking remote control, includes equipment shell (1), suction device (11), mount (14) and slide bar (21), its characterized in that: the equipment comprises an equipment shell (1), a water tank (2) is fixedly arranged in the equipment shell (1), a partition plate (3) is welded in the water tank (2), a sedimentation tank (4) is fixedly arranged in the water tank (2), a water guide pipe (5) is fixedly arranged on the right side of the water tank (2), a water pump (6) is fixedly arranged on the left side of the water tank (2), a water inlet pipe (7) and a water outlet pipe (8) are respectively arranged on the upper side and the lower side of the water pump (6), a heating bag (9) is fixed outside the water inlet pipe (7), a spraying pipe (10) is fixedly connected to the side surface of the water inlet pipe (7), an air suction device (11) is fixedly arranged in the equipment shell (1), an air inlet pipe (12) is arranged at the lower end of the air suction device (11), a transmission pipe (13) is connected to the upper end of the air suction device (11), and a fixing frame (14) is welded in the equipment shell (1), and the inboard of equipment shell (1) is connected with outlet duct (15), and the lateral surface of equipment shell (1) is provided with mounting bracket (16), the side of mounting bracket (16) and equipment shell (1) all is fixed with reinforcement ring (17), and the externally mounted of reinforcement ring (17) has bracing piece (18), and mounting bracket (16) is through side pivot (19) and equipment shell (1) interconnect, and the welding of the upper end of side pivot (19) has carousel (20) simultaneously, slide bar (21) are fixed in the side of mounting bracket (16), and the side of mounting bracket (16) is fixed with driving motor (22), and the lower extreme of driving motor (22) rotates and is connected with bottom pivot (23), bottom pivot (23) lower extreme and locating plate (24) interconnect, and the side of locating plate (24) and carousel (20) all fixedly connected with lug (25), and a push rod (26) is mounted outside the lug (25).

2. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 1, characterized in that: the device comprises a device shell (1), wherein a support (27) is fixedly mounted in the device shell (1), a controller (28) is fixedly mounted in the middle of the outer side of the support (27), and a fiber barrel (29) is arranged on the inner side of the support (27).

3. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 1, characterized in that: the sedimentation tank (4) is provided with 3 in the inside of water tank (2) at equal intervals, and the position of sedimentation tank (4) and the position of baffle (3) are crisscross to be set up to water tank (2) and transmission pipe (13) constitute intercommunication structure each other.

4. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 1, characterized in that: heating pipe (30) are installed to the inboard of heating package (9), and heating pipe (30) are connected with the laminating of the outside of inlet tube (7).

5. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 1, characterized in that: active carbon filter screen (31) are installed to the outside bilateral symmetry of mount (14), and the inside left side of mount (14) installs high pressure ionization board (32) to low pressure adsorption plate (33) are installed on the inside right side of mount (14).

6. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 1, characterized in that: mounting bracket (16) constitute revolution mechanic through side pivot (19) and equipment shell (1), and mounting bracket (16) and equipment shell (1) all with reinforcement ring (17) fixed connection to revolution mechanic is constituteed with bracing piece (18) to reinforcement ring (17).

7. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 1, characterized in that: the bottom rotating shaft (23) and the positioning plate (24) form a sliding structure, the positioning plate (24) is in sliding connection with the sliding rod (21), the positioning plate (24) and the turntable (20) are fixedly connected with the lug (25), and meanwhile, the lug (25) and the push rod (26) form a rotating structure.

8. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things as claimed in claim 2, wherein: a transmission gear (34) is installed on the outer side face of the fiber barrel (29), a rack (35) is arranged on the side face of the transmission gear (34), a transverse plate (36) is welded on the inner side of the rack (35), meanwhile, the transverse plate (36) is connected with the equipment shell (1) through a stirring rod (37), and an evaporation tube (38) is installed on the inner side of the fiber barrel (29).

9. The high-altitude gas purification treatment equipment based on the remote control of the Internet of things according to claim 8, characterized in that: the stirring rod (37) and the transverse plate (36) form a sliding structure, the transverse plate (36) and the rack (35) are of an integrated structure, and the rack (35) is meshed with the transmission gear (34).

Technical Field

The invention relates to the technical field of gas purification treatment equipment, in particular to high-altitude gas purification treatment equipment based on Internet of things remote control.

Background

Gas pollution is a relatively important pollution source in environmental pollution, industrialization is continuously developed, more and more industrial pollutants are generated, part of industrial pollutants are discharged through liquid to pollute a water source and the land, part of industrial pollutants are discharged outwards through gaseous state to pollute the air, modern industrial processing is relatively strict in pollutant discharge management, the gaseous pollutants can be discharged outwards only after being processed through corresponding processing equipment, but the processing effect of the equipment is limited, the discharged gas generally has certain pollution, the gas discharge is in high control, and the processing pollution can be reduced by further processing the gas through high-altitude processing equipment.

With the continuous processing and use of high-altitude gas purification treatment equipment, the following problems are found in the use process:

1. the high-altitude industrial exhaust gas is more, the energy consumed in the treatment process is more, and the existing part of high-altitude gas purification treatment equipment consumes more energy, so that the gas is not convenient to be treated well.

2. And the gas emission is dispersed rapidly in the high altitude, the existing part of high altitude gas treatment equipment is inconvenient to control the range of the treated gas, and the effect of the equipment for treating the gas is limited.

Therefore, the high-altitude gas purification treatment equipment based on the remote control of the internet of things is needed to be designed aiming at the problems.

Disclosure of Invention

The invention aims to provide high-altitude gas purification treatment equipment based on Internet of things remote control, and aims to solve the problems that high-altitude industrial exhaust gas is provided in the background art, energy consumed in the treatment process is high, part of the existing high-altitude gas purification treatment equipment consumes energy, gas is inconvenient to treat well, the gas exhaust is dispersed quickly in the high altitude, part of the existing high-altitude gas treatment equipment is inconvenient to control the range of the treated gas, and the effect of the equipment for treating the gas is limited.

In order to achieve the purpose, the invention provides the following technical scheme: a high-altitude gas purification treatment device based on Internet of things remote control comprises a device shell, an air suction device, a fixing frame and a sliding rod, wherein a water tank is fixedly arranged inside the device shell, a partition plate is welded inside the water tank, a sedimentation tank is fixedly arranged inside the water tank, a water guide pipe is fixedly arranged on the right side of the water tank, a water pump is fixedly arranged on the left side of the water tank, a water inlet pipe and a water outlet pipe are respectively arranged on the upper side and the lower side of the water pump, a heating bag is fixed outside the water inlet pipe, a spraying pipe is fixedly connected to the side surface of the water inlet pipe, the air suction device is fixedly arranged inside the device shell, an air inlet pipe is arranged at the lower end of the air suction device, a transmission pipe is connected to the upper end of the air suction device, the fixing frame is welded inside the device shell, an air outlet pipe is connected to the inner side of the device shell, and a mounting frame is arranged on the outer side surface of the device shell, the side of mounting bracket and equipment shell all is fixed with the reinforcement ring, and the externally mounted of reinforcement ring has the bracing piece to the mounting bracket passes through side pivot and equipment shell interconnect, and the upper end welding of side pivot has the carousel simultaneously, the slide bar is fixed in the side of mounting bracket, and the side of mounting bracket is fixed with driving motor, and driving motor's lower extreme rotates and is connected with the bottom pivot, bottom pivot lower extreme and locating plate interconnect, and the equal fixedly connected with lug in side of locating plate and carousel to the externally mounted of lug has the push rod.

Preferably, a support is fixedly mounted inside the casing, a controller is fixedly mounted in the middle of the outer side of the support, and a fiber drum is arranged inside the support.

Preferably, the sedimentation tanks are arranged in the water tank at equal intervals, the positions of the sedimentation tanks and the positions of the partition plates are staggered, and the water tank and the transmission pipe form a mutual communication structure.

Preferably, the heating pipe is installed to the inboard of heating package, and the outside laminating of heating pipe and inlet tube is connected.

Preferably, the outside both sides symmetry of mount is installed the active carbon filter screen, and the inside left side of mount installs high-pressure ionization board to the inside right side of mount installs the low pressure adsorption plate.

Preferably, the mounting bracket passes through the side pivot and constitutes revolution mechanic with equipment housing, and mounting bracket and equipment housing all with reinforcement ring fixed connection to the revolution mechanic is constituteed with the bracing piece to the reinforcement ring.

Preferably, the bottom rotating shaft and the positioning plate form a sliding structure, the positioning plate is in sliding connection with the sliding rod, the positioning plate and the turntable are both fixedly connected with the lug, and meanwhile, the lug and the push rod form a rotating structure.

Preferably, a transmission gear is installed on the outer side surface of the fiber barrel, a rack is arranged on the side surface of the transmission gear, a transverse plate is welded on the inner side of the rack, the transverse plate is connected with the equipment shell through a stirring rod, and an evaporation tube is installed on the inner side of the fiber barrel.

Preferably, the stirring rod and the transverse plate form a sliding structure, the transverse plate and the rack are of an integrated structure, and the rack is meshed with the transmission gear.

Compared with the prior art, the invention has the beneficial effects that: the high-altitude gas purification treatment equipment based on the Internet of things remote control adopts a novel structural design, so that a gas circulation treatment structure is formed in the device, the use is relatively energy-saving, a gas multi-stage treatment structure is arranged in the device, the overall gas treatment effect is relatively good, and meanwhile, a reciprocating rotation mechanism is arranged in the device, so that the range of treating high-altitude gas is conveniently expanded;

1. the device comprises sedimentation tanks arranged at equal intervals, and a water guide pipe, a water outlet pipe, a water pump, a water inlet pipe, a spray pipe and the like which are arranged on the side surface of a water tank, wherein high-altitude gas is guided into the water tank through a transmission pipe in the use process, the water pump is operated to control purification treatment liquid at the lower end of the water tank to be sprayed downwards through the spray pipe, so that the gas is rapidly settled, and pollutant components in the gas and the purification treatment liquid react with each other, so that the primary purification treatment of the gas is realized, and meanwhile, the purification treatment liquid circularly flows in the water tank, so that the use is more energy-saving;

2. the three gas treatment structures can be distributed to purify high-altitude gas, so that the gas treatment effect is improved, and the environmental pollution is reduced;

3. the equipment shell that transmission structure set up to and the locating plate that sliding structure set up, when the device operation is gaseous, control driving motor start control bottom pivot is rotated, make locating plate lateral shifting under sliding structure's control action, the locating plate passes through lug and push rod control carousel and rotates, it drives equipment shell reciprocating rotation through the side pivot to rotate, equipment shell is at reciprocating pivoted in-process, absorb the gas of the different positions in high altitude emission to equipment inside through the breathing pipe, improve equipment process gas's scope.

Drawings

FIG. 1 is a schematic cross-sectional front view of the present invention;

FIG. 2 is a front view of the turntable according to the present invention;

FIG. 3 is a schematic top view of the positioning plate of the present invention;

FIG. 4 is a schematic front view of the transmission gear of the present invention;

FIG. 5 is a schematic cross-sectional front view of a fiber cartridge of the present invention;

FIG. 6 is a front view of the fixing frame of the present invention;

FIG. 7 is a schematic sectional front view of a heating pack according to the present invention.

In the figure: 1. an equipment housing; 2. a water tank; 3. a partition plate; 4. a sedimentation tank; 5. a water conduit; 6. a water pump; 7. a water inlet pipe; 8. a water outlet pipe; 9. heating the bag; 10. a shower pipe; 11. a suction device; 12. an air inlet pipe; 13. a conveying pipe; 14. a fixed mount; 15. an air outlet pipe; 16. a mounting frame; 17. a reinforcing ring; 18. a support bar; 19. a side rotating shaft; 20. a turntable; 21. a slide bar; 22. a drive motor; 23. a bottom rotating shaft; 24. positioning a plate; 25. a bump; 26. a push rod; 27. a support; 28. a controller; 29. a fiber cartridge; 30. heating a tube; 31. an active carbon filter screen; 32. a high voltage ionization plate; 33. a low pressure adsorption plate; 34. a transmission gear; 35. a rack; 36. a transverse plate; 37. a stirring rod; 38. and (4) an evaporation tube.

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. 1-7, the present invention provides a technical solution: a high-altitude gas purification treatment device based on Internet of things remote control comprises a device shell 1, a water tank 2, a partition plate 3, a sedimentation tank 4, a water guide pipe 5, a water pump 6, a water inlet pipe 7, a water outlet pipe 8, a heating bag 9, a spray pipe 10, an air suction device 11, an air inlet pipe 12, a transmission pipe 13, a fixed frame 14, an air outlet pipe 15, a mounting frame 16, a reinforcing ring 17, a support rod 18, a side rotating shaft 19, a rotating disc 20, a sliding rod 21, a driving motor 22, a bottom rotating shaft 23, a positioning plate 24, a bump 25, a push rod 26, a support 27, a controller 28, a fiber barrel 29, a heating pipe 30, an active carbon filter screen 31, a high-pressure ionization plate 32, a low-pressure adsorption plate 33, a transmission gear 34, a rack 35, a transverse plate 36, a stirring rod 37 and an evaporation pipe 38, wherein the water tank 2 is fixedly installed inside the device shell 1, the partition plate 3 is welded inside the water tank 2, the sedimentation tank 4 is fixedly installed inside the water tank 2, a water guide pipe 5 is fixedly arranged on the right side of the water tank 2, a water pump 6 is fixedly arranged on the left side of the water tank 2, a water inlet pipe 7 and a water outlet pipe 8 are respectively arranged on the upper side and the lower side of the water pump 6, a heating bag 9 is fixed on the outer portion of the water inlet pipe 7, a spraying pipe 10 is fixedly connected to the side surface of the water inlet pipe 7, an air suction device 11 is fixedly arranged inside the device shell 1, an air inlet pipe 12 is arranged at the lower end of the air suction device 11, a transmission pipe 13 is connected to the upper end of the air suction device 11, a fixing frame 14 is welded inside the device shell 1, an air outlet pipe 15 is connected to the inner side of the device shell 1, a mounting frame 16 is arranged on the outer side surface of the device shell 1, reinforcing rings 17 are respectively fixed on the mounting frame 16 and the side surfaces of the device shell 1, supporting rods 18 are arranged on the outer portions of the reinforcing rings 17, and the mounting frame 16 is connected with the device shell 1 through side rotating shafts 19, meanwhile, the upper end of the side rotating shaft 19 is welded with the rotating disc 20, the sliding rod 21 is fixed on the side face of the mounting frame 16, the side face of the mounting frame 16 is fixed with the driving motor 22, the lower end of the driving motor 22 is rotatably connected with the bottom rotating shaft 23, the lower end of the bottom rotating shaft 23 is connected with the positioning plate 24, the positioning plate 24 and the side face of the rotating disc 20 are fixedly connected with the protruding block 25, and the push rod 26 is mounted outside the protruding block 25.

In this example, a bracket 27 is fixedly installed inside the equipment housing 1, a controller 28 is fixedly installed at the middle position of the outer side of the bracket 27, and a fiber cylinder 29 is arranged inside the bracket 27, so that the fiber cylinder 29 can absorb impurities in the evaporated gas, and the purification treatment of the dried gas is facilitated;

3 sedimentation tanks 4 are arranged in the water tank 2 at equal intervals, the positions of the sedimentation tanks 4 and the positions of the partition plates 3 are staggered, the water tank 2 and the transmission pipe 13 form a mutual communication structure, partial pollutant substances in the gas and the purification treatment liquid react with each other, the reacted sewage flows downwards, and when impurities mixed in the sewage flow to the side, the impurities are precipitated downwards when passing through the three sedimentation tanks 4, so that the gas is purified;

the heating pipe 30 is installed on the inner side of the heating bag 9, the heating pipe 30 is attached to the outer side of the water inlet pipe 7, and in the liquid transmission process, the heating pipe 30 is operated to heat the liquid in the water inlet pipe 7 according to the requirement of chemical reaction, so that the purified treatment liquid and the gas can react with each other conveniently in the later period;

activated carbon filter screens 31 are symmetrically arranged on two sides of the outer portion of the fixed frame 14, a high-pressure ionization plate 32 is arranged on the left side of the inner portion of the fixed frame 14, a low-pressure adsorption plate 33 is arranged on the right side of the inner portion of the fixed frame 14, when gas in the equipment shell 1 enters the fixed frame 14, the high-pressure ionization plate 32 and the low-pressure adsorption plate 33 are remotely controlled to be powered on and operated, the molecular structure of part of polluting impurities is damaged when the gas passes through the middle of the high-pressure ionization plate 32, and then the impurities in the gas pass through the low-pressure adsorption plate 33 and are subjected to adsorption treatment;

the mounting frame 16 and the equipment shell 1 form a rotating structure through the side rotating shaft 19, the mounting frame 16 and the equipment shell 1 are fixedly connected with the reinforcing ring 17, the reinforcing ring 17 and the supporting rod 18 form a rotating structure, and the supporting rod 18 and the reinforcing ring 17 can be arranged to reinforce and support the mounting structure of the equipment shell 1, so that the stability of the equipment shell 1 in the rotating process is improved;

the bottom rotating shaft 23 and the positioning plate 24 form a sliding structure, the positioning plate 24 is slidably connected with the sliding rod 21, the positioning plate 24 and the turntable 20 are fixedly connected with the lug 25, meanwhile, the lug 25 and the push rod 26 form a rotating structure, when the rotary table is used, the driving motor 22 is operated to control the bottom rotating shaft 23 to rotate, the turntable 20 is made to rotate in a reciprocating manner under the control of the transmission structure, and the side rotating shaft 19 is used for controlling the equipment shell 1 to rotate in an equal angle in a reciprocating manner;

a transmission gear 34 is installed on the outer side surface of the fiber cylinder 29, a rack 35 is arranged on the side surface of the transmission gear 34, a transverse plate 36 is welded on the inner side of the rack 35, the transverse plate 36 is connected with the equipment shell 1 through a stirring rod 37, an evaporation tube 38 is installed on the inner side of the fiber cylinder 29, the fiber cylinder 29 can be controlled to rotate through a meshing transmission structure, and the fiber cylinder 29 can perform drying adsorption treatment on gas in the equipment shell 1 in the transmission process to realize purification treatment on the gas;

the stirring rod 37 and the transverse plate 36 form a sliding structure, the transverse plate 36 and the rack 35 are of an integrated structure, the rack 35 is meshed with the transmission gear 34, and when the stirring rod 37 rotates, gas is uniformly distributed outside the fiber barrel 29.

The working principle is as follows: when the device is used, firstly, the device is installed in an area with concentrated high-altitude gas emission according to the structure shown in figures 1 and 7, circuit operation structures in the device are connected with background equipment through a remote control structure, so that the operation of each circuit structure is controlled step by step through the internet of things, air suction equipment 11 is operated to suck the high-altitude gas into the equipment through an air inlet pipe 12, the gas enters the water tank 2 through a transmission pipe 13, a water pump 6 is operated at the same time, purified treatment liquid at the lower end of the water tank 2 enters the spraying pipe 10 through a water outlet pipe 8 and a water inlet pipe 7 under the action of negative pressure (in the liquid transmission process, a heating pipe 30 is operated to heat the liquid in the water inlet pipe 7 according to the requirement of chemical reaction), the liquid sprayed downwards by the spraying pipe 10 is mutually contacted with the gas entering the water tank 2, and particle dust in the gas is rapidly settled, and some polluting substances in the gas react with the purifying treatment liquid, the treated liquid flows downwards, when impurities mixed in the sewage flow to the side, the impurities precipitate downwards when passing through the three sedimentation tanks 4, then the liquid flows to the lower end of the water tank 2 through the water guide pipe 5, the liquid in the water tank 2 is sequentially precipitated again in the area isolated by the partition plate 3, the circularly flowing purifying treatment liquid is treated, the quality of the purifying treatment liquid is improved, and meanwhile, the energy saving property of the device for treating the gas is improved through the circular treatment structure, and the energy consumption of the device is reduced;

then, according to the structure shown in fig. 1, 4, 5 and 6, after the gas is primarily treated by the water tank 2, the gas enters the upper end of the equipment shell 1, the motor in the equipment shell 1 is remotely controlled to operate, the stirring rod 37 rotates, the stirring rod 37 pushes the transverse plate 36 to move back and forth in a reciprocating manner in the rotating process, the transverse plate 36 drives the racks 35 on the two sides to move back and forth, the racks 35 are meshed with the transmission gear 34, the fiber cylinder 29 rotates in a reciprocating manner under the control of the meshed transmission structure, the evaporation tube 38 is remotely controlled to be started by the controller 28, the evaporation tube 38 is heated, the gas is uniformly dispersed outside the fiber cylinder 29 under the rotating and dispersing effect of the stirring rod 37, the gas can be dried when the evaporation tube 38 is heated, meanwhile, the dried gas is in contact with the outside of the fiber cylinder 29, impurities in the gas are adsorbed on the outside of the fiber cylinder 29, the gas is dried and purified, then the gas moves to the right side of the equipment shell 1 and enters the next purification area, the high-pressure ionization plate 32 and the low-pressure adsorption plate 33 are remotely controlled to be electrified to operate, the molecular structure of partial pollutant impurities is damaged when the gas passes through the middle of the high-pressure ionization plate 32, then the impurities in the gas pass through the low-pressure adsorption plate 33 are adsorbed, finally, the purified gas is discharged outwards through the gas outlet pipe 15, and the partial structure can purify the high-altitude gas in a grading mode in sequence, so that the gas treatment effect of the device is improved;

then, according to the structure shown in fig. 1, fig. 2 and fig. 3, while the device purifies the process gas, the device controls the device housing 1 to rotate in a regular reciprocating manner, the driving motor 22 is operated to control the bottom rotating shaft 23 to rotate, the bottom rotating shaft 23 is connected with the positioning plate 24 in a sliding manner, the bottom rotating shaft 23 pushes the positioning plate 24 to slide in a transverse direction outside the sliding rod 21 in the rotating process, the positioning plate 24 drives the protrusion 25 fixed at the lower end to move in a transverse direction, the protrusion 25 controls the rotating disc 20 to rotate in an equiangular reciprocating manner through the push rod 26 connected in a rotating manner at the outer side (the length of the bottom rotating shaft 23 is less than half of the length of the push rod 26, so the transmission structure can control the rotating disc 20 to rotate in a reciprocating manner through a certain angle through the push rod 26), the rotating disc 20 drives the device housing 1 at the outer side to rotate in a reciprocating manner through the side rotating shaft 19 (in the rotating process of the device housing 1, both sides of the supporting rod 18 arranged corresponding to the upper and the lower side are respectively rotated with the reinforcing ring 17, the supporting rod 18 and the reinforcing ring 17 can be used for reinforcing and supporting the mounting structure of the equipment shell 1, so that the stability of the equipment shell 1 in the rotating process is improved), the equipment shell 1 can absorb and process the gas at different positions in the high altitude through the gas inlet pipe 12, the range of the device for processing the gas in the high altitude is improved, and the gas processing effect of the equipment is improved.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.