CN117816334A - Intelligent analysis device for cement grinding system - Google Patents

Abstract

The invention provides an intelligent analysis device for a cement grinding system, which relates to the field of cement processing, wherein particles of a first powder selecting machine and a second powder selecting machine are detected through a particle size detector, then material particles which do not accord with the particle size are ground through a ball mill, the load of the ball mill is detected through a load detector in the grinding process, so that the material particles in the ball mill are in a certain balance state, the material particles are quickly ground through the ball mill, then qualified material particles are collected through a second dust collecting component, the unqualified material particles are ground through a ball mill which is added for a second time after being screened through a second powder selecting machine, and the collected material particles are ground through a third hopper until the particle sizes accord with the particle sizes, and the particle sizes of the collected material particles of the first dust collecting component, the second dust collecting component and the third dust collecting component can be detected through the powder selecting machine detector, and when the particle sizes do not accord with each other, the air quantity of an air blowing component is adjusted timely.

Description

Intelligent analysis device for cement grinding system

Technical Field

The application relates to the field of cement processing, in particular to an intelligent analysis device for a cement grinding mill system.

Background

The cement production process flow comprises three procedures: cement raw material mill, cement firing and cement mill. Wherein, the working procedure of the cement mill is as follows: proportioning, grinding, selecting powder and conveying. According to different cement varieties, setting corresponding material proportions, feeding the prepared mixture into a steady flow bin, feeding the mixture into a roller press, feeding the material from the roller press into a V-shaped powder concentrator, returning coarse particles into the steady flow bin through the lower part of the V-shaped powder concentrator, and feeding smaller particles into a ball mill. The materials after being ground by the ball mill enter a powder selecting machine, coarse particle materials are fed into the ball mill again for continuous grinding, and qualified fine powder is collected and conveyed to a finished product warehouse. However, the existing system has the disadvantages of low and unstable on-site compressed air pressure, poor representativeness of the sampling position of the open mill and inaccurate measurement data of a comparison table, and in order to ensure the stable operation of an on-line particle size analyzer, the compressed air is rectified for a plurality of times: a booster pump is configured, a small air compressor is configured, a gas storage tank is configured and other measures are taken; replacing the sampling point a plurality of times: the on-line particle size analyzer has larger application and maintenance amount in the open-flow grinding system in the whole parts of the open-flow grinding tail chute, the out-grinding bucket lifting chute, the warehouse bucket lifting chute, the finished product conveying chute and the like.

Disclosure of Invention

An object of the embodiment of the application is to provide an intelligent analysis device for a cement grinding mill system, which can solve the technical problems.

The embodiment of the application provides an intelligent analysis device for a cement grinding system, which comprises a cement grinding device, a granularity detector, a load detector, a powder concentrator detector and a controller, wherein the cement grinding device comprises a feeding belt, a first hopper, a roller press, a first powder concentrator, a second powder concentrator, a first dust collecting component, a ball mill, a second hopper, a second dust collecting component, a third hopper, a third dust collecting component and a blowing component, the discharging end of the feeding belt is connected with the feeding end of the first hopper, the discharging end of the first hopper is connected with the feeding end of the roller press, the discharging end of the roller press is connected with the feeding end of the first powder concentrator through the second hopper, the upper end of the first powder concentrator is connected with the first dust collecting component, the discharging end of the ball mill is respectively connected with the feeding end of the third hopper, the second dust collecting component is connected with the blowing component, the second powder concentrator is arranged between the first powder concentrator and the first powder concentrator, the second dust collecting component is arranged between the first powder concentrator and the first powder concentrator, the second powder concentrator is arranged between the second hopper and the first powder concentrator, the second powder concentrator is arranged between the first powder concentrator and the second powder concentrator, the second powder concentrator is arranged between the first powder concentrator and the first powder concentrator, the first powder concentrator is arranged between the second powder concentrator is arranged between the first powder concentrator and the first powder concentrator, the first powder concentrator is connected with the second powder concentrator, the first powder concentrator is arranged between the powder collector, the powder collector is connected with the first powder collector, the powder collector is arranged between the material, the load detector, the powder concentrator detector, the roller press and the ball mill are electrically connected.

Preferably, the granularity detector comprises a detection pipeline, a laser transmitter, a Fourier mirror and a main detector, wherein the upper end and the lower end of the detection pipeline are connected with a blanking pipeline of the first powder concentrator or a blanking pipeline of the second powder concentrator, the laser transmitter, the Fourier mirror and the main detector are sequentially and transversely arranged on the detection pipeline, and the detection pipeline is positioned between the laser transmitter and the Fourier mirror.

Preferably, the upper end and the lower end of the detection pipeline are arc-shaped, and the upper end of the detection pipeline is provided with a vent hole.

Preferably, the load detector comprises a noise detection sensor, a wireless transmitting module, a wireless receiving module and a control cabinet, wherein the noise detection sensor is installed on the outer wall of the ball mill, the noise detection sensor is electrically connected with the wireless generating module, and the wireless generating module can transmit received data to the control cabinet through the wireless receiving module.

Preferably, the noise detection sensor may be provided in plurality.

Preferably, the powder concentrator detector comprises a spiral sampler, a vibrating screen plate, a static sampling port and a detection sensor, wherein the spiral sampler is aligned with the feeding end of the first dust collecting assembly, the second dust collecting assembly and the third dust collecting assembly, the vibrating screen plate is mounted at the lower end of the spiral sampler, the static sampling port is mounted below the vibrating screen plate, and the detection sensor is mounted in the static sampling port.

Preferably, the vibrating screen plate is obliquely arranged, and the aperture of the vibrating screen plate is sequentially reduced from high to low.

Preferably, the first dust collecting component, the second dust collecting component and the third dust collecting component are all externally connected with an exhaust fan, and a sieve plate is arranged between the exhaust fan and the first dust collecting component, between the exhaust fan and the second dust collecting component, and between the exhaust fan and the third dust collecting component.

Preferably, the controller is a PLC.

Preferably, the first dust collection assembly, the second dust collection assembly and the third dust collection assembly comprise a plurality of dust collectors, and the plurality of dust collectors are arranged in an array.

The invention has the beneficial effects that:

the invention provides an intelligent analysis device for a cement mill system, which comprises a cement mill device, a particle size detector, a load detector, a powder concentrator detector and a controller, wherein the cement mill device comprises a feeding belt, a first hopper, a roller press, a first powder concentrator, a second powder concentrator, a first dust collecting component, a ball mill, a second hopper, a second dust collecting component, a third hopper, a third dust collecting component and a gas blowing component, the discharging end of the feeding belt is connected with the feeding end of the first hopper, the discharging end of the first hopper is connected with the feeding end of the roller press through the second hopper, the upper end of the roller press is connected with the first dust collecting component, the lower end of the powder concentrator is connected with the feeding end of the ball mill, the discharging end of the ball mill is respectively connected with the feeding end of the third hopper, the second dust collecting component is connected with the third dust collecting component, the second hopper is connected with the first dust collector, the first dust collector is arranged in the ball mill, the first dust collector is arranged between the second hopper and the first dust collector, the second dust collector is arranged between the first powder concentrator and the first dust collector, the second dust collector is arranged between the first dust collector and the first dust collector, the first dust collector is arranged between the second hopper and the first dust collector is connected with the first dust collector, the first dust collector is arranged between the first dust collector and the first dust collector is arranged, and the dust collector is connected with the dust collector, the dust collector is arranged between the dust collector is connected with the dust collector, the load detector, the powder concentrator detector, the roller press and the ball mill are electrically connected, the first powder concentrator and the second powder concentrator are detected through the particle size detector, then the material particles which do not accord with the particle size are polished through the ball mill, the load detector is used for detecting the load of the ball mill in the polishing process, when the load is too low, the material particles are added, when the load is too high, the addition of the material particles is reduced, the material particles in the ball mill are in a certain balance state, the material particles are rapidly polished through the ball mill, then the qualified material particles are collected through the second dust collecting assembly, the unqualified material particles are polished through the ball mill which is subjected to secondary dust collecting through the third dust collecting assembly after being screened through the second powder concentrator, until the polishing accords with the particle size, and the particle size of the collected material particles of the first dust collecting assembly, the second dust collecting assembly and the third dust collecting assembly can be detected through the powder concentrator detector, and when the particle size of the collected material particles does not accord with the first dust collecting assembly, the air outlet quantity of the air pumping assembly can be adjusted timely.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered limiting the scope, and that other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a schematic diagram of the particle size detector of the present invention;

FIG. 3 is a schematic diagram of the load detector of the present invention;

fig. 4 is a schematic diagram of the detector structure of the powder concentrator of the present invention.

The reference numerals are respectively:

1. a cement mill device; 2. a granularity detector; 3. a load detector; 4. a powder concentrator detector; 5. a controller; 6. a feeding belt; 7. a first bucket; 8. a roller press; 9. a first powder concentrator; 10. a second powder concentrator; 11. a first dust collection assembly; 12. ball mill; 13. a second bucket; 14. a second dust collection assembly; 15. a third bucket lift; 16. a third dust collection assembly; 17. a gas blowing assembly; 18. detecting a pipeline; 19. a laser emitter; 20. a fourier mirror; 21. a main detector; 22. a vent hole; 23. a noise detection sensor; 24. a wireless transmission module; 25. a wireless receiving module; 26. a control cabinet; 27. a spiral sampler; 28. vibrating the screen plate; 29. a static sampling port; 30. a detection sensor; 31. and an exhaust fan.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, which are generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, as provided in the accompanying drawings, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present application, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships that are conventionally put in use of the product of the application, are merely for convenience of description of the present application and simplification of description, and are not indicative or implying that the apparatus or element to be referred to must have a specific direction, be configured and operated in a specific direction, and therefore should not be construed as limiting the present application. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal," "vertical," "overhang," and the like do not denote a requirement that the component be absolutely horizontal or overhang, but rather may be slightly inclined. As "horizontal" merely means that its direction is more horizontal than "vertical", and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present application, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

As shown in fig. 1-4, an intelligent analysis device for a cement mill system comprises a cement mill device 1, a particle size detector 2, a load detector 3, a powder concentrator detector 4 and a controller 5, wherein the cement mill device 1 comprises a feeding belt 6, a first hopper 7, a roller press 8, a first powder concentrator 9, a second powder concentrator 10, a first dust collection assembly 11, a ball mill 12, a second hopper 13, a second dust collection assembly 14, a third hopper 15, a third dust collection assembly 16 and a gas blowing assembly 17, the discharge end of the feeding belt 6 is connected with the feed end of the first hopper 7, the discharge end of the first hopper 7 is connected with the feed end of the first powder concentrator 9 through the second hopper 13, the upper end of the first powder concentrator 9 is connected with the first dust collection assembly 11, the lower end of the second powder concentrator 12 is connected with the ball mill 12, the third hopper 15 is respectively connected with the second hopper 12, the first powder concentrator 10 is mounted with the second hopper 10, the third powder concentrator assembly 16 is mounted with the second hopper 10, the first powder concentrator 10 is mounted with the third powder concentrator 10, the first powder concentrator 10 is mounted with the third hopper 10 at the discharge end of the first hopper 9 is connected with the feed end of the first powder concentrator 9, the air blowing component 17 is used for blowing compressed air into the first powder concentrator 9 and the second powder concentrator 10, the controller 5 is respectively and electrically connected with the granularity detector 2, the load detector 3, the powder concentrator detector 4, the roller press 8 and the ball mill 12, the granularity detector 2 is used for detecting the particles of the first powder concentrator 9 and the second powder concentrator, the ball mill 12 is used for polishing the particles of the materials which do not meet the granularity, the load detector is used for detecting the load of the ball mill 12 in the polishing process, when the load is too low, the material particles are added, when the load is too high, the material particles are reduced, so that the material particles in the ball mill 12 are in a certain balance state, the material particles are rapidly polished through the ball mill 12, qualified material particles are collected through the second dust collecting component 14, the unqualified material particles are polished through the ball mill 12 which is added for the second time after being screened through the second powder concentrator 10, until the polished material particles which meet the granularity, and the first dust collecting component 4 and the second dust collecting component 16 are used for detecting the particles which meet the granularity, and the third dust collecting component 16 is used for collecting the dust collecting the particles, and when the dust collecting component is not met, and the dust collecting component is used for collecting the dust.

As shown in fig. 1-4, the invention can control the air output of the air blowing component 17, the rotating speed of the ball mill 12, the feeding and discharging amount entering the ball mill 12, the rotating speed of the roller press 8 and the like through the controller 5.

In this embodiment, as shown in fig. 1-2, the particle size detector 2 includes a detection pipe 18, a laser emitter 19, a fourier mirror 20, and a main detector 21, where the upper and lower ends of the detection pipe 18 are connected to the blanking pipe of the first powder separator 9 or the blanking pipe of the second powder separator 10, the laser emitter 19, the fourier mirror 20, and the main detector 21 are sequentially and transversely installed on the detection pipe 18, the detection pipe 18 is located between the laser emitter 19 and the fourier mirror 20, and the laser generator emits laser, after the laser diverges through the fourier mirror 20, when the laser passes through the blanking pipe, a part of the laser is blocked by particles in the blanking pipe, and the other part of the laser is emitted to the main detector 21, the main detector 21 sends the detected signal to the dust collection controller 5, and the material particles conforming to the particle size are collected by the first powder separator 11, and the material particles not conforming to the particle size are sent to the ball mill 12 for polishing.

In this embodiment, the upper end and the lower end of the detection pipeline 18 are arc-shaped, and the upper end of the monitoring pipeline is provided with a vent hole 22, and after the material particles in the detection pipeline 18 are detected, the material particles are sent into the first powder concentrator 9 or the second powder concentrator 10 through the detection pipeline 18.

As shown in fig. 1 and 3, in this embodiment, the load detector 3 includes a noise detection sensor 23, a wireless transmitting module 24, a wireless receiving module 25, and a control cabinet 26, where the noise detection sensor 23 is mounted on an outer wall of the ball mill 12, the noise detection sensor 23 is electrically connected to the wireless generating module, the wireless generating module may transmit received data to the control cabinet 26 through the wireless receiving module 25, the noise detection sensor 23 may be provided with a plurality of noise detection sensors 23, the noise detection sensor 23 detects noise inside the ball mill 12, the mounting point of the noise detection sensor 23 is polished by a polishing machine, the noise detection sensor 23 is mounted on a fixing base plate is fixed on the ball mill 12 by using a metal glue and is compressed for more than one hour, and according to a preset suitable noise value, when the noise value is lower than the preset noise value, it indicates that the material particles inside the ball mill 12 are less to be added, when the noise value is higher than the preset noise value, and when the material particles inside the ball mill 12 are too much to be added, the noise value is reduced, and according to the preset noise value, the required size is selected, and the suitable size can be selected.

As shown in fig. 1 and 4, in this embodiment, the powder concentrator detector 4 includes a spiral sampler 27, a vibrating screen plate 28, a static sampling port 29, and a detection sensor 30, the spiral sampler 27 is aligned to the feeding ends of the first dust collecting component 11, the second dust collecting component 14, and the third dust collecting component 16, the vibrating screen plate 28 is installed at the lower end of the spiral sampler 27, the static sampling port 29 is installed below the vibrating screen plate 28, the detection sensor 30 is installed in the static sampling port 29, the vibrating screen plate 28 is obliquely arranged, the aperture of the vibrating screen plate 28 is sequentially reduced from high to low, the size of the material particles at the feeding ends of the first dust collecting component 11, the second dust collecting component 14, and the third dust collecting component 16 is pumped by the spiral sampler 27, the material particles at the feeding ends of the first dust collecting component 11, the second dust collecting component 14, and the third dust collecting component 16 are screened by the vibrating screen plate 28, the static sampling port 29 is installed below the vibrating screen plate 28, the size of the material particles is reduced when the size of the air is detected by the static screen plate 28, and the size of the air is reduced when the air is blown by the air, and the air is required to be filtered by the blower 17.

As shown in fig. 1, in this embodiment, the first dust collecting assembly 11, the second dust collecting assembly 14, and the third dust collecting assembly 16 are all externally connected with an exhaust fan 31, and a sieve plate is disposed between the exhaust fan 31 and the first dust collecting assembly 11, between the exhaust fan 31 and the second dust collecting assembly 14, and between the exhaust fan 31 and the third dust collecting assembly 16, and the exhaust fan 31 is used for rapidly exhausting air entering the first dust collecting assembly 11, the second dust collecting assembly 14, and the third dust collecting assembly 16, and the sieve plate can prevent material particles from being exhausted from the exhaust fan 31.

In this embodiment, the controller 5 is a PLC.

In this embodiment, as shown in fig. 1, the first dust collecting component 11, the second dust collecting component 14, and the third dust collecting component 16 each include a plurality of dust collectors, where a plurality of the dust collectors are arranged in an array, and the dust collectors are used for collecting qualified material particles.

The foregoing is merely a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and variations may be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (10)

1. An intelligent analysis device for a cement mill system, characterized in that: comprises a cement grinding mill device, a granularity detector, a load detector, a powder selecting machine detector and a controller, wherein the cement grinding mill device comprises a feeding belt, a first bucket elevator, a roller press, a first powder selecting machine, a second powder selecting machine, a first dust collecting component, a ball mill, a second bucket elevator, a second dust collecting component, a third bucket elevator, a third dust collecting component and an air blowing component, the discharging end of the feeding belt is connected with the feeding end of the first bucket elevator, the discharging end of the first bucket elevator is connected with the feeding end of the roller press, the discharging end of the roller press is connected with the feeding end of the first powder selecting machine through the second bucket elevator, the upper end of the first powder selecting machine is connected with the first dust collecting component, the lower end of the powder selecting machine is connected with the feeding end of the ball mill, the discharging end of the ball mill is respectively connected with the feeding end of the third bucket elevator and the second dust collecting component, the discharge end of the third hopper is connected with the feed end of the second powder concentrator, the lower end of the second powder concentrator is connected with the feed end of the ball mill, the upper end of the second powder concentrator is connected with the third dust collection component, the particle size detector is arranged on the first powder concentrator and the second powder concentrator, the load detector is arranged on the ball mill, the powder concentrator detector is arranged between the first powder concentrator and the first dust collection component, between the second powder concentrator and the third dust collection component and between the ball mill and the second dust collection component, the air blowing component is used for blowing compressed air into the first powder concentrator and the second powder concentrator, and the controller is respectively connected with the particle size detector, the load detector, the powder concentrator detector, the roller press and the air blowing component, the ball mill is electrically connected.

2. An intelligent analysis device for a cement grinding system according to claim 1, wherein: the granularity detector comprises a detection pipeline, a laser emitter, a Fourier mirror and a main detector, wherein the upper end and the lower end of the detection pipeline are connected with a blanking pipeline of the first powder concentrator or a blanking pipeline of the second powder concentrator, the laser emitter, the Fourier mirror and the main detector are sequentially and transversely arranged on the detection pipeline, and the detection pipeline is positioned between the laser emitter and the Fourier mirror.

3. An intelligent analysis device for a cement grinding system according to claim 2, wherein: the upper end and the lower end of the detection pipeline are arc-shaped, and the upper end of the monitoring pipeline is provided with a vent hole.

4. An intelligent analysis device for a cement grinding system according to claim 1, wherein: the load detector comprises a noise detection sensor, a wireless transmitting module, a wireless receiving module and a control cabinet, wherein the noise detection sensor is arranged on the outer wall of the ball mill, the noise detection sensor is electrically connected with the wireless generating module, and the wireless generating module can transmit received data to the control cabinet through the wireless receiving module.

5. An intelligent analysis device for a cement grinding system as defined in claim 4, wherein: the noise detection sensor may be provided in plurality.

6. An intelligent analysis device for a cement grinding system according to claim 1, wherein: the powder concentrator detector comprises a spiral sampler, a vibrating screen plate, a static sampling port and a detection sensor, wherein the spiral sampler is aligned with the feeding end of the first dust collecting assembly, the second dust collecting assembly and the third dust collecting assembly, the vibrating screen plate is arranged at the lower end of the spiral sampler, the static sampling port is arranged below the vibrating screen plate, and the detection sensor is arranged in the static sampling port.

7. An intelligent analysis device for a cement grinding system as defined in claim 6, wherein: the vibrating screen plate is obliquely arranged, and the aperture of the vibrating screen plate is sequentially reduced from high to low.

8. An intelligent analysis device for a cement grinding system according to claim 1, wherein: the first dust collecting assembly, the second dust collecting assembly and the third dust collecting assembly are all externally connected with an exhaust fan, and a sieve plate is arranged between the exhaust fan and the first dust collecting assembly, between the exhaust fan and the second dust collecting assembly, between the exhaust fan and the third dust collecting assembly.

9. An intelligent analysis device for a cement grinding system according to claim 1, wherein: the controller is a PLC.

10. An intelligent analysis device for a cement grinding system according to claim 1, wherein: the first dust collection assembly, the second dust collection assembly and the third dust collection assembly comprise a plurality of dust collectors which are arranged in an array.