CN221267509U - High-efficient dust particle interception separator - Google Patents

Abstract

The utility model belongs to the technical field of dust treatment, and particularly relates to a high-efficiency dust particle interception and separation device, which comprises a shell and a second filter box arranged at one end of the shell, wherein a powder particle interception and filtration mechanism is arranged between the shell and the second filter box, a large-particle-size particle interception and filtration mechanism is arranged in the shell and comprises a baffle plate arranged in the shell, a plurality of interception components are arranged on the inner side of the baffle plate, each interception component comprises two connecting plates, the two connecting plates are respectively positioned on two sides of the inside of the baffle plate, and three cylinders are rotationally connected between the two connecting plates. According to the utility model, through the large-particle-diameter particle interception filtering mechanism, accurate control of particle interception degree under different operation conditions is realized, and adaptability and flexibility of the device are remarkably improved. The device can be used for capturing various particles with high efficiency and simultaneously can be operated reliably and efficiently in complex and changeable working environments.

Description

High-efficient dust particle interception separator

Technical Field

The utility model belongs to the technical field of dust treatment, and particularly relates to a high-efficiency dust particle interception and separation device.

Background

The high-efficiency dust particle interception and separation device is important for preventing the diffusion of fine particles, purifying air and improving the environmental quality.

Current interception devices typically employ fixed filtration structures, which have significant drawbacks in adapting to particle size and operating environment. Thus, existing devices may exhibit problems of low interception efficiency when handling dust particles of different sizes and properties. This limitation affects the overall performance of the device in practical applications, and it is necessary to remedy these drawbacks by innovative technical solutions.

Disclosure of utility model

The utility model aims to provide a high-efficiency dust particle interception and separation device, which can realize accurate control of particle interception degree under different operation conditions and remarkably improve adaptability and flexibility of the device. The device can be used for capturing various particles with high efficiency and simultaneously can be operated reliably and efficiently in complex and changeable working environments.

The technical scheme adopted by the utility model is as follows:

The utility model provides a high-efficient dust particle interception separator, includes the second rose box of casing and its one end installation, just be provided with powder particle interception filter mechanism between casing and the second rose box, the inside of casing is provided with big particle diameter particle interception filter mechanism, big particle diameter particle interception filter mechanism includes casing internally mounted's baffle, a plurality of interception subassemblies are installed to the inboard of baffle, and every interception subassembly all includes two connecting plates, and two connecting plates are located the inside both sides of baffle respectively, two rotate between the connecting plates and be connected with three cylinder, the outside of cylinder is fixed with the filter, the bottom of filter is fixed with the rotation post, all rotate between rotation post and baffle and rotation post and the casing and be connected, the one end of rotation post is fixed with the revolving plate, just the revolving plate is located the outside of casing, still be provided with drive assembly on the casing.

At least three supporting legs are fixed at the bottom of the shell.

The large-particle-size particle interception filtering mechanism further comprises a discharging assembly, the discharging assembly comprises a continuous weighing device arranged among a plurality of supporting legs, an electric valve and a pipeline are arranged on the continuous weighing device, the pipeline is communicated with the electric valve through a hose, a hopper box is arranged at the bottom of the shell, and the electric valve is arranged at the bottom of the hopper box.

The driving assembly comprises a driving motor arranged on the outer side of the shell, connecting pieces are arranged between every two adjacent rotating plates, every two connecting pieces which are close to each other are respectively positioned at the two ends of the rotating plates, two ends of each connecting piece are respectively connected with one end of each rotating plate which is close to each other in a rotating way, and the output end of the driving motor is fixedly connected with one rotating plate.

A plurality of first interception plates and second interception plates are arranged on the inner side of the top of the funnel box.

The utility model has the technical effects that:

According to the utility model, through the large-particle-diameter particle interception filtering mechanism, accurate control of particle interception degree under different operation conditions is realized, and adaptability and flexibility of the device are remarkably improved. The device can be used for capturing various particles with high efficiency and simultaneously can be operated reliably and efficiently in complex and changeable working environments.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the inside of the housing of the present utility model;

FIG. 3 is a schematic structural view of a large particle size particle interception filter mechanism of the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. A housing; 2. a wind speed sensor; 3. a large-particle-diameter particle interception and filtration mechanism; 4. a first interception plate; 5. a second interception plate; 6. an electric valve; 7. a hose; 8. a continuous scale; 9. a particle sensor; 10. a powder particle interception and filtration mechanism; 11. a driving motor; 12. a dust concentration detector; 13. a remote particle cutter; 14. a hopper box; 15. a second filter box; 16. a pipe; 17. a partition plate; 18. rotating the column; 19. a filter plate; 20. a connecting plate; 21. a connecting piece; 22. a cylinder; 23. support legs; 24. and (5) rotating the plate.

Detailed Description

The present utility model will be specifically described with reference to examples below in order to make the objects and advantages of the present utility model more apparent. It should be understood that the following text is intended to describe only one or more specific embodiments of the utility model and does not limit the scope of the utility model strictly as claimed.

As shown in fig. 1-3, a high-efficiency dust particle interception and separation device comprises a shell 1 and a second filter box 15 arranged at one end of the shell, wherein a powder particle interception and filtration mechanism 10 is arranged between the shell 1 and the second filter box 15;

wherein, be provided with the air intake of being connected with the external world on the casing 1, the one end that second rose box 15 kept away from casing 1 is provided with the air outlet.

In addition, a large-particle-diameter particle interception and filtration mechanism 3 is arranged in the shell 1, the large-particle-diameter particle interception and filtration mechanism 3 comprises a baffle 17 arranged in the shell 1, a plurality of interception components are vertically arrayed on the inner side of the baffle 17, each interception component comprises two connecting plates 20, the two connecting plates 20 are respectively positioned on two sides of the inner part of the baffle 17, three cylinders 22 are rotationally connected between the two connecting plates 20, the three cylinders 22 are respectively positioned at two ends and the middle position of the connecting plates 20, a filter plate 19 is fixed on the outer side of the cylinders 22, a rotary column 18 is fixed at the middle position of the bottom of the filter plate 19, two ends of the rotary column 18 penetrate through the baffle 17 and the inner part of the shell 1, the rotary column 18 is rotationally connected with the baffle 17 and the rotary column 18 and the shell 1, one end of the rotary column 18 is fixedly provided with a rotary plate 24, and the rotary plate 24 is positioned on the outer side of the shell 1;

referring to fig. 3, a connecting piece 21 is disposed between every two adjacent rotating plates 24, each two connecting pieces 21 close to each other are respectively located at two ends of the rotating plates 24, and two ends of each connecting piece 21 are respectively connected with one end of each two rotating plates 24 close to each other in a rotating manner;

the driving motor 11 is also installed on the outer side of the shell 1, and the output end of the driving motor 11 is fixedly connected with one of the rotating plates 24.

According to the above structure, the external air enters the housing 1 from the air inlet, passes through the large particle size particle interception and filtration mechanism 3 and the powder particle interception and filtration mechanism 10, and passes through gaps among the plurality of filter plates 19 in the process, larger particles can be removed through the filter plates 19, and tiny particles can be captured by the powder particle interception and filtration mechanism 10, and finally is discharged through the air outlet;

And through the operation of the driving motor 11, one rotating plate 24 can rotate, the other connecting pieces 21 can be driven to rotate through the connecting pieces 21, so that the rotating column 18 and the connecting plates 20 can drive the filter plates 19 to rotate, gaps among the filter plates 19 can be adjusted, and large particle screening can be adjusted to adapt to interception of particles with different sizes;

The external air enters the shell 1 from the air inlet and sequentially passes through the large-particle-diameter particle interception and filtration mechanism 3 and the powder particle interception and filtration mechanism 10, in the process, the air flows through gaps among the filter plates 19, large particles can be removed through the gaps, tiny particles are captured by the powder particle interception and filtration mechanism 10, and finally clean air is discharged through the air outlet.

In addition, the operation of the driving motor 11 causes one of the rotating plates 24 to rotate, and the other connecting members 21 are rotated together by the connecting members 21. This movement is transmitted to the plurality of filter plates 19 through the rotation posts 18 and the connection plates 20, thereby adjusting the gaps between the plurality of filter plates 19. The mechanism can flexibly adjust the size of the gap so as to adapt to the interception requirements of particles with different sizes.

In sum, through large-particle-diameter particle interception filtering mechanism 3, the degree of particle interception can be accurately controlled under different operating conditions, and the adaptability and the flexibility of the device are further improved. This not only means that the system is able to capture various types of particles with high efficiency, but also ensures reliable and efficient operation of the device in complex and diverse operating environments. The device can rapidly and accurately adapt to the interception requirements of different dust particles, and provides a solid foundation for the excellent performance of the device in actual work.

Referring to fig. 1 and 2, in addition, at least three support legs 23 are fixed at the bottom of the shell 1 through bolts, and mounting seats are arranged at the bottoms of the support legs 23, when in use, the support legs 23 with the adaptive length can be replaced according to specific use requirements, and the shell 1 can be fixed on the ground or a bracket through the mounting seats, so that an air inlet on the shell 1 is adaptive to an air outlet of an external device;

Meanwhile, the large-particle-diameter particle interception filtering mechanism 3 further comprises a blanking assembly, the blanking assembly comprises a continuous weighing device 8, a bearing plate is arranged among a plurality of supporting legs 23, the continuous weighing device 8 is arranged on the bearing plate, a hopper box 14 is further fixed at the bottom of the shell 1, an electric valve 6 fixed at the bottom of the hopper box 14 and a pipeline 16 capable of being connected with an external garbage can or a collecting box are arranged on the continuous weighing device 8, and the pipeline 16 is communicated with the electric valve 6 through a hose 7;

According to the above structure, when the removed larger particles and the captured fine particles can fall into the funnel box 14, the particles in the funnel box 14 can be continuously weighed by the continuous scale 8, once the mass of the particles in the funnel box 14 reaches the preset value set by the continuous scale 8, the continuous scale 8 sends out an early warning signal, and the electric valve 6 starts to operate, so that the particles are discharged into the external garbage can or the collecting box through the pipeline 16.

With reference to fig. 1, a particle sensor 9 is furthermore provided on the pipe 16 for detecting the mass of the discharged particles or other relevant parameters. This provides real-time particle analysis data for the user, facilitating centralized processing.

In addition, the housing 1 is provided with precise instruments on the second filter box 15, which comprises a long-range particle cutter 13 and a dust concentration detector 12, wherein the long-range particle cutter 13 is used for acquiring particle samples, the comprehensiveness and accuracy of monitoring are improved, and the dust concentration detector 12 is used for measuring and recording the dust concentration in the system. The system performance can be known at any time by operators, and necessary measures are taken to maintain and optimize the operation of the system, so that the high-efficiency operation of the device is maintained, the operators can more effectively cope with the changes under different working conditions, and the device is ensured to be always in the optimal performance state;

And a wind speed sensor 2 is also provided on the housing 1 to measure the speed of the gas through the system. For controlling the wind speed to remain within a suitable range.

A plurality of first interception plates 4 and second interception plates 5 are installed at the top inner side of the hopper tank 14, aiming at effectively preventing particles having been intercepted from falling into the inside of the hopper tank 14 again and being discharged into the environment. To achieve this, it is possible to ensure safe handling of the intercepted particles by means of a clever design of the collection and storage system.

The shell 1 is also provided with a control host, and the electric valve 6, the continuous scale 8, the particle sensor 9, the powder particle interception and filtration mechanism 10, the driving motor 11, the dust concentration detector 12 and the long-range particle cutter 13 are all electrically connected with the control host.

The control host, the electric valve 6, the continuous weighing device 8, the particle sensor 9, the powder particle interception and filtration mechanism 10, the driving motor 11, the dust concentration detector 12 and the remote particle cutter 13 are all of the prior art, and detailed descriptions thereof are omitted in this embodiment.

In summary, the utility model has the following beneficial effects:

The adaptability is improved: the adjustable large-particle-diameter particle interception filtering mechanism 3 enables the system to adapt to particles with different particle diameters, and improves the applicability and interception efficiency of the system.

Intelligent waste treatment: the automatic management to the granule has been realized to unloading subassembly, through real-time supervision and accurate control, has improved waste material treatment's efficiency and convenience.

Monitoring system performance in real time: the application of the precise instrument enables a user to know the running condition of the system at any time, is convenient for timely adjustment and maintenance, and ensures that the system works in an optimal state.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims (7)

1. The utility model provides a high-efficient dust particle interception and separation device, includes casing (1) and its one end second rose box (15) of installation, just be provided with powder particle interception and filtration mechanism (10), its characterized in that between casing (1) and second rose box (15): the inside of casing (1) is provided with big particle diameter granule interception filtering mechanism (3), big particle diameter granule interception filtering mechanism (3) are including casing (1) internally mounted's baffle (17), a plurality of interception subassemblies are installed to the inboard of baffle (17), and every interception subassembly all includes two connecting plates (20), and two connecting plates (20) are located the inside both sides of baffle (17) respectively, two rotate between connecting plates (20) and be connected with three cylinder (22), the outside of cylinder (22) is fixed with filter (19), the bottom of filter (19) is fixed with rotation post (18), all rotate between rotation post (18) and baffle (17) and rotation post (18) and casing (1) and be connected, the one end of rotation post (18) is fixed with revolving plate (24), just revolving plate (24) are located the outside of casing (1), still be provided with drive assembly on casing (1).

2. The efficient dust particle interception and separation device according to claim 1, wherein: at least three supporting legs (23) are fixed at the bottom of the shell (1).

3. The efficient dust particle interception and separation device according to claim 2, wherein: the large-particle-size particle interception filtering mechanism (3) further comprises a discharging assembly, the discharging assembly comprises a continuous weighing device (8) arranged among a plurality of supporting legs (23), an electric valve (6) and a pipeline (16) are arranged on the continuous weighing device (8), the pipeline (16) and the electric valve (6) are communicated through a hose (7), a hopper box (14) is arranged at the bottom of the shell (1), and the electric valve (6) is arranged at the bottom of the hopper box (14).

4. A high efficiency dust particle interception and separation device according to claim 3, wherein: the pipeline (16) is also provided with a particle sensor (9).

5. The efficient dust particle interception and separation device according to claim 1, wherein: the shell (1) and the second filter box (15) are respectively provided with a long-distance particle cutter (13) and a dust concentration detector (12), and the shell (1) is also provided with a wind speed sensor (2).

6. The efficient dust particle interception and separation device according to claim 1, wherein: the driving assembly comprises a driving motor (11) arranged on the outer side of the shell (1), connecting pieces (21) are arranged between every two adjacent rotating plates (24), every two connecting pieces (21) which are close to each other are respectively located at two ends of the rotating plates (24), two ends of each connecting piece (21) are respectively connected with one end of each rotating plate (24) which is close to each other in a rotating mode, and the output end of the driving motor (11) is fixedly connected with one of the rotating plates (24).

7. A high efficiency dust particle interception and separation device according to claim 3, wherein: a plurality of first interception plates (4) and second interception plates (5) are arranged on the inner side of the top of the funnel box (14).