CN113897209B

CN113897209B - Intelligent feed bin based on lacquer sediment recovery processing

Info

Publication number: CN113897209B
Application number: CN202111489968.1A
Authority: CN
Inventors: 徐立农
Original assignee: Jiangsu Ruidesi Environmental Protection Technology Co ltd
Current assignee: Jiangsu Ruidesi Environmental Protection Technology Co ltd
Priority date: 2021-12-08
Filing date: 2021-12-08
Publication date: 2022-02-18
Anticipated expiration: 2041-12-08
Also published as: CN113897209A

Abstract

The invention discloses an intelligent storage bin based on paint slag recovery processing, and relates to the technical field of intelligent storage bins.

Description

Intelligent feed bin based on lacquer sediment recovery processing

Technical Field

The invention relates to the technical field of intelligent storage bins, in particular to an intelligent storage bin based on paint slag recovery processing.

Background

The method is characterized in that residues generated by paint production waste or residues generated by peeling off of coated paint are called paint residues, assembly line paint coating is carried out, a large amount of paint flies to be atomized and flocculated into a water tank, a small assembly line is required to salvage and filter dozens of or even hundreds of kilograms of paint mist coagulation residues every day, a large spraying line is required to salvage hundreds of kilograms of flocculated paint residues every day, for corrosion prevention, the surfaces of steel and iron parts such as ships, automobiles, containers, bridges and the like basically use paint, the using amount of the paint is increased year by year, the generated paint residues are not ignored, a large amount of waste paint residues are generated in the manufacturing industries such as the ships, the containers, the bridges and the like, the ships, the containers and the bridges are regularly painted, and the number of the scraped waste paint residues is extremely large;

the existing paint slag recovery treatment process comprises the following steps: collecting paint slag subjected to crushing, magnetic separation and drying into a bin, pouring the dried paint slag into a circulating fluidized bed through a conveyor to obtain pyrolysis oil gas and pyrolysis ash solid, collecting the pyrolysis oil gas, condensing the pyrolysis oil gas through a condenser, performing oil-water separation in an oil-water separator, recovering an organic solvent for other dissolved additives, collecting the pyrolysis ash solid, grinding the pyrolysis ash solid into micro powder filler, and using the micro powder filler for production of low-end alkyd paint to finish paint slag recovery treatment, wherein the bin is required to be used in the process;

for example, a paint slag comprehensive utilization device of the utility model publication No. CN207174952U uses a semi-finished product bin to realize temporary storage and discharge of paint slag materials, so that the operation and function of the whole paint slag recovery processing process are more reasonable and flexible, and the orderly execution of the paint slag recovery process is ensured;

however, the method has some disadvantages that when the paint slag is large, the circulating fluidized bed is easy to pyrolyze dynamically, the pyrolyzed paint slag is not sufficient, and continuous feeding causes accumulation of materials in the circulating fluidized bed, so that the paint slag in the circulating fluidized bed is further increased, the high-efficiency operation of the circulating fluidized bed is influenced, the pyrolysis is sufficient, and the mixed gas is easy to mix, meanwhile, the paint slag cannot be ground by the conventional storage bin, so that the paint slag is easier to pyrolyze in subsequent processing, and cannot be automatically adjusted with a paint slag recovery processing device or process, the material is accurately proportioned, the storage bin is low in intelligence, needs frequent manual operation, and is not simple and convenient enough;

in view of the above technical drawbacks, a solution is proposed.

Disclosure of Invention

The invention aims to: by arranging the storage bin, the feeding part, the discharging hopper, the discharging pipe, the fine grinding component, the fine matching component and the sieving device, on the basis of realizing fine grinding and screening and accurate batching, the system is also provided with an information acquisition module, a data operation module, a processor, a material supplementing calculation module and an element execution module, by collecting, running, calculating and executing information in the paint slag recycling and processing process, the intelligent and precise batching in the paint slag recycling and processing process is realized, the pyrolysis oil gas and the pyrolysis solid state in the paint slag recycling and processing process are in a dynamic balance state, the pyrolysis quality is optimal, the reaction effect is optimal, the reaction efficiency is fastest, the function of automatically feeding materials to the storage bin and reminding and recording the feeding materials is realized, and the problem that the traditional storage bin is low in intelligence and cannot feed back with other components in the paint slag recycling and processing process in time is solved.

In order to achieve the purpose, the invention adopts the following technical scheme:

the intelligent storage bin based on paint slag recovery processing comprises a storage bin, wherein a feeding part and a discharging hopper are respectively arranged at two ends of the storage bin, a control panel is further installed at the outer end of the bottom of the storage bin, and the control panel is electrically connected with a display screen and a starting button; the discharging pipe is fixedly arranged at the bottom end of the discharging hopper, the feeding part, the storage bin, the discharging hopper and the discharging pipe are sequentially communicated from top to bottom, the fine grinding component and the screening device are installed at the feeding part, the screening device is arranged right below the fine grinding component, and the fine matching component is installed in the discharging hopper;

the precise matching assembly comprises a U-shaped material passing ring plate, a U-shaped distribution ring sleeve, a U-shaped damping ring sleeve, a second servo motor and a fifth rotating rod, wherein the bottom end of the U-shaped material passing ring plate is fixedly connected with the bottom end of the discharge hopper, the second servo motor is fixedly arranged at the bottom end of the middle part of the U-shaped material passing ring plate, the fifth rotating rod is rotatably arranged at the center of the U-shaped material passing ring plate, one end of the fifth rotating rod is fixedly connected with an output shaft of the second servo motor, the other end of the fifth rotating rod penetrates through the U-shaped material passing ring plate and then is fixedly connected with the U-shaped distribution ring sleeve, the U-shaped damping ring sleeve is arranged between the U-shaped distribution ring sleeve and the U-shaped material passing ring plate, the outer end of the U-shaped damping ring sleeve is abutted against the U-shaped distribution ring sleeve, the inner end of the U-shaped damping ring sleeve is fixedly sleeved on the outer end of the U-shaped material passing ring plate, the U-shaped material passing ring plate is provided with a plurality of first material passing holes, and the U-shaped distribution ring sleeve is provided with a plurality of second material passing holes, the first material passing holes and the second material passing holes are distributed in an annular array by taking a central axis of a fifth rotating rod as a circle center, a plurality of the first material passing holes are equidistantly reduced, the U-shaped distribution ring sleeve is provided with a third material passing hole, the third material passing hole is movably communicated and connected with one of the first material passing holes, the bottom end of the U-shaped material passing ring plate is arranged on the inner side wall of the discharge hopper and is in sliding connection with the discharge hopper, and the bottom end of the U-shaped distribution ring sleeve is fixedly provided with a limiting ring boss;

the control panel comprises an information acquisition module, a data operation module, a processor, an element execution module and a material supplementing calculation module;

the information acquisition module is used for acquiring working condition environment information and pyrolysis condition information of the material slag in the circulating fluidized bed and sending the information to the data operation module, and also acquiring residual volume information of the paint slag in the storage bin and sending the information to the material supplementing calculation module;

the data operation module is used for receiving working condition environment information and pyrolysis condition information of the material slag in the circulating fluidized bed, generating an intelligent material distribution factor of the material bin, comparing the intelligent material distribution factor of the material bin with a preset range value, generating an accurate material distribution control signal and sending the accurate material distribution control signal to the element execution module;

the material supplementing calculation module is used for receiving the residual volume information of the paint slag in the storage bin, calculating to obtain a precise material supplementing factor of the storage bin, comparing the generated precise material supplementing factor of the storage bin with a preset value, generating a material supplementing early warning prompt signal and sending the material supplementing early warning prompt signal to the element execution module;

and the element execution module is used for receiving the control signal and controlling the corresponding component to work.

Furthermore, the outer end of the U-shaped distribution ring sleeve is provided with a guide chute which is communicated with the third material passing hole.

Furthermore, the third material passing hole and the second material passing hole are equal in caliber, and the section of the top end of the U-shaped distribution ring, which is sleeved at the joint of the U-shaped distribution ring and the fifth rotating rod, is arc-shaped.

Further, the fine grinding component comprises a coarse grinding roller, a first rotating rod, a first fine grinding roller, a second rotating rod, a second fine grinding roller, a third rotating rod and a first servo motor, the coarse grinding roller is symmetrically provided with two rotating rods, the coarse grinding rollers are meshed with each other and used for crushing paint slag, the first rotating rod is rotatably connected with the feeding portion, the first rotating rod is symmetrically provided with two rotating rods, the outer end of the first rotating rod is fixedly sleeved with the coarse grinding roller, one end of the first rotating rod penetrates through the inner wall of the feeding portion and extends to the outside of the feeding portion, the first rotating rod is fixedly sleeved with a first gear, the coarse grinding roller is arranged right above the first fine grinding roller, the first fine grinding roller is abutted against the second fine grinding roller, the first fine grinding roller is symmetrically arranged on two sides of the second fine grinding roller, and the second rotating rod and the third rotating rod are rotatably arranged in the feeding portion, two second rotating rods are arranged, the second rotating rods are symmetrically arranged at two sides of the third rotating rod, the outer ends of the second rotating rods and the third rotating rods are respectively fixedly sleeved with the first fine grinding roller and the second fine grinding roller, one end of the second rotating rod penetrates through the inner wall of the feeding part and extends to the outside of the feeding part, a second gear is fixedly sleeved on the second rotating rod, one end of the third rotating rod penetrates through the inner wall of the feeding part and extends to the outside of the feeding part, and is fixedly sleeved with a third gear and a fourth gear, the first servo motor is fixedly arranged at the center of one side of the feeding part, the output shaft of the first servo motor is fixedly connected with a fourth rotating rod, one end of the fourth rotating rod is fixedly sleeved with a fifth gear and a sixth gear, the fifth gear is in transmission connection with the first gear through a gear chain, the sixth gear is in transmission connection with the fourth gear through a toothed chain, and one third gear is in transmission connection with the two second gears through the toothed chain.

Furthermore, the working condition environment information in the circulating fluidized bed collected by the information collection module consists of an air pressure value in the reaction cavity of the circulating fluidized bed, a temperature value in the reaction cavity of the circulating fluidized bed and a temperature value outside the reaction cavity of the circulating fluidized bed, and the pyrolysis condition information of the slag consists of the volume of pyrolysis oil gas and the weight of pyrolysis ash solids.

Further, the residual volume information of the paint slag in the storage bin, which is acquired by the information acquisition module, is composed of the total consumption of the paint slag flowing through the refined assembly and the real-time volume of the paint slag in the storage bin.

Further, the specific working steps of the data operation module are as follows:

sa: after receiving the working condition environment information and the pyrolysis condition information of the material slag in the circulating fluidized bed, the data operation module respectively calibrates the air pressure value in the circulating fluidized bed reaction cavity, the temperature value outside the circulating fluidized bed reaction cavity, the volume of pyrolysis oil gas and the weight of pyrolysis ash solid in the circulating fluidized bed reaction cavity, and calculates according to a formula to obtain an intelligent material distribution factor A of the storage bin;

sb: comparing an intelligent batching factor A of the real-time generated storage bin with a preset range value a, generating a first accurate batching control signal when A is less than amin, and generating a second accurate batching control signal when A is more than amax; when a = a, no control signal is generated;

and (C) Sc: and sending the first accurate batching control signal or the second accurate batching control signal generated in real time to the element execution module through the processor.

Further, the concrete working steps of the feed supplement calculation module are as follows:

sa: the material supplementing calculation module receives the total consumption of paint slag flowing through the fine matching component and the real-time paint slag volume in the storage bin, and after the total consumption and the real-time paint slag volume are respectively calibrated, the accurate material supplementing factor B of the storage bin is obtained through formula calculation;

sb: comparing the generated accurate feed supplement factor B of the storage bin with a preset value B, and generating a feed supplement early warning prompt signal when B is less than or equal to B, otherwise, not generating the feed supplement early warning prompt signal;

and (C) Sc: and the generated feeding early warning prompt signal is sent to an element execution module.

Further, the specific working steps of the element execution module are as follows:

sa: when the element execution module receives the first accurate batching control signal, the accurate batching component is immediately controlled to increase the supply of the paint slag in the reaction cavity of the circulating fluidized bed;

sb: when the second accurate batching control signal is received and generated, the accurate batching component is immediately controlled to reduce the supply of the accurate batching component to the material;

and (C) Sc: when the element execution module receives the feeding early warning prompt signal, immediately editing a feeding early warning text, sending the feeding early warning text to a display screen for displaying and flashing, wherein the feeding early warning text is 'the paint slag reaches a use early warning value, and please a worker to accelerate the feeding of the paint slag into the storage bin'; the feeding early warning text is used for reminding workers of feeding materials in time;

simultaneously, paint slag is immediately added to the feeding part, the fine grinding assembly and the sieving device are started, the material is filled in the storage bin until the material in the storage bin reaches a preset paint slag volume value, and then the material filling early warning text is controlled to stop flashing, and the automatic material filling text is edited and displayed on the display screen; wherein the automatic feeding text is 'automatically feeding for the nth time', and n is a positive integer.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

the invention is characterized in that the device comprises a storage bin, a feeding part, a discharge hopper, a discharge pipe, a fine grinding component, a fine matching component and a screening device, on the basis of realizing fine grinding and screening and accurate batching, the system is also provided with an information acquisition module, a data operation module, a processor, a material supplementing calculation module and an element execution module, the invention realizes intelligent precise batching in the paint slag recovery processing process, ensures that pyrolysis oil gas and pyrolysis solid state are in a dynamic balance state in the paint slag recovery processing process, optimizes pyrolysis quality, ensures that the reaction effect is optimal and the reaction efficiency is fastest, also realizes the functions of automatically feeding materials to a storage bin and reminding and recording the feeding materials, and solves the problems that the traditional storage bin is low in intelligence and cannot feed back with other components in the paint slag recovery processing process in time.

Drawings

FIG. 1 shows a front view of the present invention;

FIG. 2 shows a partial enlargement at the feed section;

FIG. 3 shows a cross-sectional view at the feed section;

FIG. 4 shows a schematic structural diagram of a precision assembly;

FIG. 5 shows a partial enlarged view at A of FIG. 4;

FIG. 6 illustrates a flow chart of the intelligent operation of the present invention;

illustration of the drawings: 1. a storage bin; 2. a feeding section; 3. a discharge hopper; 4. a discharge pipe; 5. a finish grinding assembly; 6. precisely assembling the components; 7. a sifter; 101. a control panel; 102. a display screen; 103. a start button; 501. a rough grinding roller; 502. a first rotating lever; 503. a first gear; 504. a first fine grinding roller; 505. a second rotating rod; 506. a second gear; 507. a second fine grinding roller; 508. a third rotating rod; 509. a third gear; 510. a fourth gear; 511. a first servo motor; 512. a fourth rotating rod; 513. a fifth gear; 514. a sixth gear; 601. a U-shaped feed ring plate; 602. a U-shaped distribution collar; 603. a U-shaped damping ring sleeve; 604. a first material passing hole; 605. a second material passing hole; 606. a third material passing hole; 607. a material guide chute; 608. the limiting ring is convex; 609. a second servo motor; 610. and a fifth rotating rod.

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. 1-6, the present invention provides a technical solution:

intelligent feed bin based on paint slag recovery processing, comprising a storage bin 1, wherein a feeding part 2 and a discharging hopper 3 are respectively arranged at two ends of the storage bin 1, a discharging pipe 4 is fixedly arranged at the bottom end of the discharging hopper 3, the feeding part 2, the storage bin 1, the discharging hopper 3 and the discharging pipe 4 are sequentially communicated from top to bottom, a fine grinding component 5 and a sieving device 7 are arranged at the feeding part 2, the fine grinding component 5 grinds the crushed paint slag for multiple times, paint slag particles are finely ground into powder, the sieving device 7 is arranged under the fine grinding component 5, the sieving device 7 is used for sieving the powder paint slag, the particle size of the paint slag is between 100 and 200 micrometers, the storage bin 1 stores the powder paint slag, a fine matching component 6 is arranged in the discharging hopper 3, the fine matching component 6 is used for accurately matching a circulating fluidized bed, a control panel 101 is further arranged at the outer end of the bottom of the storage bin 1, the control panel 101 is electrically connected with a display screen 102 and a start button 103, the start button 103 is used to start the device;

the control panel 101 comprises an information acquisition module, a data operation module, a processor, an element execution module and a material supplementing calculation module;

the information acquisition module is used for acquiring working condition environment information and pyrolysis condition information of the material slag in the circulating fluidized bed and sending the information to the data operation module, and also acquiring residual volume information of the paint slag in the storage bin 1 and sending the information to the material supplementing calculation module;

the material supplementing calculation module is used for receiving the residual volume information of the paint slag in the storage bin 1, calculating to obtain a precise material supplementing factor of the storage bin, comparing the generated precise material supplementing factor of the storage bin with a preset value, generating a material supplementing early warning prompt signal and sending the material supplementing early warning prompt signal to the element execution module

The element execution module is used for receiving the control signal and controlling the corresponding component to work;

the fine grinding assembly 5 comprises a coarse grinding roller 501, a first rotating rod 502, a first fine grinding roller 504, a second rotating rod 505, a second fine grinding roller 507, a third rotating rod 508 and a first servo motor 511, wherein the coarse grinding rollers 501 are symmetrically arranged in two, the coarse grinding rollers 501 are mutually meshed and are used for crushing paint slag, the first rotating rod 502 is rotatably connected with the feeding part 2, the first rotating rod 502 is symmetrically provided with two rotating rods, the outer end of the first rotating rod 502 is fixedly sleeved with the coarse grinding roller 501, one end of one first rotating rod 502 penetrates through the inner wall of the feeding part 2 to extend to the outer part of the feeding part and is fixedly sleeved with a first gear 503, the coarse grinding roller 501 is arranged right above the first fine grinding roller 504, the first fine grinding roller 504 is abutted against the second fine grinding roller 507, the first fine grinding roller 504 is symmetrically arranged on two sides of the second fine grinding roller 507, the second rotating rod 505 and the third rotating rod 508 are rotatably arranged in the feeding part 2, two second rotating rods 505 are provided, and the second rotating rods 505 are symmetrically provided at both sides of the third rotating rod 508, the outer ends of a second rotating rod 505 and a third rotating rod 508 are fixedly sleeved with a first fine grinding roller 504 and a second fine grinding roller 507 respectively, one end of the second rotating rod 505 penetrates through the inner wall of the feeding part 2 to extend to the outside of the feeding part and is fixedly sleeved with a second gear 506, one end of the third rotating rod 508 penetrates through the inner wall of the feeding part 2 to extend to the outside of the feeding part and is fixedly sleeved with a third gear 509 and a fourth gear 510, a first servo motor 511 is fixedly arranged at the center of one side of the feeding part 2, an output shaft of the first servo motor 511 is fixedly connected with a fourth rotating rod 512, one end of the fourth rotating rod 512 is fixedly sleeved with a fifth gear 513 and a sixth gear 514, the fifth gear 513 is in transmission connection with the first gear 503 through a toothed chain, the sixth gear 514 is in transmission connection with the fourth gear 510 through a toothed chain, and one third gear 509 is in transmission connection with two second gears 506 through a toothed chain;

after paint slag enters from the feeding part 2 and falls onto the rough grinding roller 501, the first servo motor 511 is started and the output shaft of the first servo motor 511 is controlled to rotate, the output shaft of the first servo motor 511 rotates to drive the fourth rotating rod 512 fixed with the first servo motor to rotate, the fourth rotating rod 512 rotates to drive the fifth gear 513 and the sixth gear 514 fixedly sleeved with the fourth rotating rod to rotate, the fifth gear 513 and the sixth gear 514 respectively drive the first gear 503 and the fourth gear 510 in transmission connection with the fifth gear through a toothed chain, the first gear 503 rotates to drive one of the first rotating rods 502 fixedly sleeved with the first gear to rotate, one of the first rotating rods 502 rotates to drive the rough grinding roller 501 fixedly sleeved with the rough grinding roller 501 to rotate, the rough grinding roller 501 rotates to drive the other rough grinding roller 501 engaged with the rough grinding roller 501 to rotate, the other rough grinding roller 501 rotates to drive the other first rotating rod 502 fixedly sleeved with the rough grinding roller 502 to rotate, two coarse grinding rollers 501 are meshed to synchronously rotate to extrude and crush paint slag falling into the coarse grinding rollers, coarse grinding is carried out to ensure that the paint slag is changed into coarse particles, meanwhile, a fourth gear 510 rotates to drive a third rotating rod 508 fixed with the fourth gear to rotate, the third rotating rod 508 rotates to respectively drive a third gear 509 fixedly sleeved with the third rotating rod and a second fine grinding roller 507 to rotate, the third gear 509 rotates to simultaneously drive two second gears 506 to rotate through a toothed chain, the second gear 506 rotates to drive a second rotating rod 505 fixedly sleeved with the second gear to rotate, the second rotating rod 505 rotates to drive a first fine grinding roller 504 fixedly sleeved with the second rotating rod to rotate, the two first fine grinding rollers 504 and a second fine grinding roller 507 rotate to further extrude and grind the paint slag of the coarse particles to ensure that the paint slag of the coarse particles is changed into fine particles, and by combining the working steps, one motor synchronously drives the coarse grinding rollers 501, the second fine grinding rollers 501, the third rotating rod and the third rotating rod 508 to rotate, The first fine grinding roller 504 and the second fine grinding roller 507 rotate synchronously, so that coarse grinding and fine grinding of paint slag are realized, subsequent pyrolysis reaction is more sufficient, and the pyrolysis efficiency is improved;

the fine matching component 6 comprises a U-shaped material passing ring plate 601, a U-shaped distribution ring sleeve 602, a U-shaped damping ring sleeve 603, a second servo motor 609 and a fifth rotating rod 610, wherein the bottom end of the U-shaped material passing ring plate 601 is fixedly connected with the bottom end of the discharge hopper 3, the second servo motor 609 is fixedly arranged at the bottom end of the middle part of the U-shaped material passing ring plate 601, the fifth rotating rod 610 is rotatably arranged at the center of the U-shaped material passing ring plate 601, one end of the fifth rotating rod 610 is fixedly connected with an output shaft of the second servo motor 609, the other end of the fifth rotating rod 610 penetrates through the U-shaped material passing ring plate 601 and is fixedly connected with the U-shaped distribution ring sleeve 602, the U-shaped damping ring sleeve 603 is arranged between the U-shaped distribution ring sleeve 602 and the U-shaped material passing ring plate 601, the outer end of the U-shaped damping ring sleeve 603 is abutted against the U-shaped distribution ring sleeve 602, the inner end of the U-shaped damping ring sleeve 603 is fixedly sleeved on the outer end of the U-shaped material passing ring plate 601, a plurality of first material passing holes are formed in the U-shaped material passing ring plate 601, the U-shaped distribution ring sleeve 602 is provided with a plurality of second material passing holes 605, the first material passing holes 604 and the second material passing holes 605 are distributed in an annular array by taking the central axis of the fifth rotating rod 610 as the center, the plurality of first material passing holes 604 are equidistantly reduced, the U-shaped distribution ring sleeve 602 is provided with a third material passing hole 606, the third material passing hole 606 is movably communicated and connected with one of the first material passing holes 604, the outer end of the U-shaped distribution ring sleeve 602 is provided with a material guide groove 607, the material guide groove 607 is communicated and connected with the third material passing holes 606, the material guide groove 607 guides the fine particulate paint slag to the third material passing hole 606, so that the flow of the fine particulate paint slag distribution material is smoother, wherein the diameters of the third material passing hole 606 and the second material passing holes 605 are equal, namely the third material passing hole 606 is equal to the first material passing hole 604 with the largest diameter, the cross section of the U-shaped distribution ring sleeve 602 at the connecting part with the fifth rotating rod 610 is arc-shaped distribution ring sleeve 602, the fine-particle paint slag is distributed more smoothly, the bottom end of the U-shaped through material ring plate 601 is arranged on the inner side wall of the discharge hopper 3 and is connected with the inner side wall in a sliding manner, the bottom end of the U-shaped distribution ring sleeve 602 is fixedly provided with a limiting ring bulge 608, and the limiting ring bulge 608 is embedded into a ring groove formed in the U-shaped through material ring plate 601 in a sliding manner;

when the amount of the paint slag required by the circulating fluidized bed is not equal, the second servo motor 609 is started to work and the output shaft of the second servo motor 609 is controlled to rotate, the output shaft of the second servo motor 609 drives the fifth rotating rod 610 fixed with the second servo motor 609 to rotate, the fifth rotating rod 610 drives the U-shaped distribution ring sleeve 602 fixedly connected with the fifth rotating rod to rotate, the position of the third material passing hole 606 is changed after the U-shaped distribution ring sleeve 602 rotates, then the third material passing hole 606, the second material passing hole 605 and the first material passing hole 604 are connected with the second material passing hole 605 and the first material passing hole 604, the third material passing hole 606 respectively penetrates through the first material passing holes 604 with different calibers through the second material passing hole 605 by controlling the rotation angle of the output shaft of the second servo motor 609 through the steps, and the first material passing holes 604 have different calibers because the calibers of the first material passing holes 604 are different in size, so that the amount of the paint slag passing through the first material passing holes 604 is different, the output shaft of the second servo motor 609 is controlled to rotate at a fixed angle for one time and is driven by the components to drive the U-shaped distribution ring sleeve 602 to rotate, so that the middle points of the third material passing hole 606, the second material passing hole 605 and the first material passing hole 604 are in the same straight line, thereby the flow rate of the paint slag is maximized, the output shaft of the second servo motor 609 is controlled to rotate at a fixed angle for two times, so that the middle points of the third material passing hole 606, the second material passing hole 605 and the first material passing hole 604 are not in the same straight line, the first material passing hole 604 and the third material passing hole 606 are partially overlapped, the overlap ratio of the first material passing hole 604 and the third material passing hole 606 is controlled, wherein the higher the overlap ratio of the first material passing hole 604 and the third material passing hole 606 is, the larger the flow rate of the paint slag is, and the smaller the flow rate of the paint slag is otherwise, the technical scheme is synthesized, the flow rate of the paint slag is accurately controlled, and the work of accurately batching the paint slag is realized, the paint slag of the circulating fluidized bed is kept in a constant state;

the working principle is as follows:

step one, pre-storing certain fine grinding paint slag: pouring the crushed and dried paint slag from the top of the feeding part 2, starting the fine grinding assembly 5 and the sieving device 7 by the control panel 101 to perform fine grinding and sieving on the paint slag respectively, then dropping the sieved paint slag with the target particle size into the storage bin 1, scanning the real-time paint slag volume in the storage bin 1 by the infrared light curtain volume measuring instrument, and closing the fine grinding assembly 5 and the sieving device 7 until the real-time paint slag volume in the storage bin 1 scanned by the infrared light curtain volume measuring instrument reaches a preset paint slag volume value;

secondly, the information acquisition module acquires working condition environment information and pyrolysis condition information of the material slag in the circulating fluidized bed and sends the information to the data operation module; the working condition environment information in the circulating fluidized bed consists of an air pressure value in a circulating fluidized bed reaction cavity, a temperature value in the circulating fluidized bed reaction cavity, which is sensed by a pressure sensor, and a temperature value outside the circulating fluidized bed reaction cavity, which is sensed by a first temperature sensor, and the pyrolysis condition information of the material slag consists of the volume of pyrolysis oil gas, which is sensed by a gas flow sensor, and the weight of pyrolysis ash solid, which is sensed by a weight sensor; the temperature difference between the inside and the outside of the reaction cavity of the circulating fluidized bed is large, so that the temperature in the reaction cavity of the circulating fluidized bed is not stable enough and is easy to run off, and the pyrolysis of the material slag is influenced; paint slag with the same volume or weight is added into the circulating fluidized bed for pyrolysis, and the larger the volume of pyrolysis oil gas and the weight of pyrolysis ash solid is, the more sufficient the pyrolysis is, and the higher the pyrolysis efficiency is;

step three, after the data operation module receives the working condition environment information in the circulating fluidized bed and the pyrolysis condition information of the material slag, respectively marking the air pressure value in the circulating fluidized bed reaction cavity, the temperature value outside the circulating fluidized bed reaction cavity, the volume of pyrolysis oil gas and the weight of pyrolysis ash solid in the circulating fluidized bed reaction cavity as W, E, R, T and Y, and then respectively marking the air pressure value, the temperature value in the circulating fluidized bed reaction cavity, the temperature value outside the circulating fluidized bed reaction cavity, the volume of pyrolysis oil gas and the weight of pyrolysis ash solid as W, E, R, T and Y according to a formula

Obtaining an intelligent batching factor A of the stock bin, wherein e₁、e₂、e₃、e₄、e₅And e₆Is a weight correction coefficient which enables the calculation result of the intelligent batching factor A of the storage bin to be closer to the true value, and e₂＜e₄＜e₃＜e₅＜e₁＜e₆，e₁+e₂+e₃+e₄+e₅+e₆=17.18；

Comparing an intelligent batching factor A of the real-time generated storage bin with a preset range value a, generating a first accurate batching control signal when A is less than amin, and generating a second accurate batching control signal when A is more than amax; when A = a, no control signal is generated, wherein A = a indicates that A is within a range of a preset range value a;

the first accurate batching control signal or the second accurate batching control signal generated in real time is sent to the element execution module through the processor;

after receiving the first accurate batching control signal, the element execution module immediately controls the accurate batching component 6 to increase the supply of the paint slag in the reaction cavity of the circulating fluidized bed;

when the second accurate batching control signal is received and generated, the accurate batching component 6 is immediately controlled to reduce the supply of the accurate batching component 6 to the material;

step five, the information acquisition module also passes through the consumption total amount of the finish assembly 6 and the real-time paint slag volume in the storage bin 1 scanned by the infrared light curtain volume measuring instrument through the paint slag acquired by the powder flow sensor and sends the real-time paint slag volume to the paint slag calculation module; the residual volume information of the paint slag in the storage bin 1 is accurately formed by the consumption total amount of the paint slag flowing through the precise assembly 6 and the real-time paint slag volume in the storage bin 1, so that the storage bin 1 is reminded of feeding and automatic grinding; wherein the automatic grinding can be shut off manually;

step six, the material supplementing calculation module receives the total passing consumption of the paint slag flowing through the fine matching assembly 6 and the real-time paint slag volume in the storage bin 1, respectively marks the total passing consumption and the real-time paint slag volume as U and P, and then passes through a formula

Obtaining the accurate feed supplement factor of the stock binB; wherein k is₁、k₂And k₃In order to simulate the correction factor, the result of the calculation of the accurate feed supplement factor B of the storage bin is closer to the true value by the simulated correction factor, and k is₁＞k₃＞k₂，k₁+k₂+k₃= 5.16; the generated accurate feed supplement factor B of the storage bin is compared with a preset value B, and when B is less than or equal to B, a feed supplement early warning prompt signal is generated, otherwise, the feed supplement early warning prompt signal is not generated; the generated feeding early warning prompt signal is sent to an element execution module;

step seven, after the component execution module receives the feeding early warning prompt signal, immediately editing a feeding early warning text and sending the feeding early warning text to the display screen 102 for displaying and flashing, wherein the feeding early warning text is that the paint slag reaches a use early warning value and the worker is required to accelerate the feeding of the paint slag into the storage bin; the feeding early warning text is used for reminding workers of feeding materials in time;

simultaneously, paint slag is immediately added to the feeding part 2, the fine grinding assembly 5 and the sieving device 7 are started, the material is filled in the storage bin 1 until the material in the storage bin 1 reaches a preset paint slag volume value, then the material supplementing early warning text is controlled to stop flashing, and an automatic material supplementing text is edited and displayed on the display screen 102, wherein the automatic material supplementing text is 'automatic material supplementing for the nth time', and n is a positive integer;

by integrating the technical scheme, the invention realizes the intelligent precise batching in the paint slag recovery processing process by arranging the storage bin 1, the feeding part 2, the discharge hopper 3, the discharge pipe 4, the fine grinding assembly 5, the fine batching assembly 6 and the sieving device 7, and by arranging the information acquisition module, the data operation module, the processor, the material supplementing calculation module and the element execution module on the basis of realizing the fine grinding, sieving and precise batching, and by acquiring, operating, calculating and executing the working condition environment information in the circulating fluidized bed and the pyrolysis condition information of the material slag in the paint slag recovery processing process, so that the pyrolysis oil gas and the pyrolysis solid state are in a dynamic balance state in the paint slag recovery processing process, the pyrolysis quality is optimal, the reaction effect is optimal, the reaction efficiency is fastest, and the high-efficiency intelligent operation of the whole process is assisted, the paint slag flows through the precise matching assembly 6, the consumption total amount and the real-time paint slag volume in the storage bin 1 are collected, calculation and execution are performed, the automatic material supplementing for the storage bin 1 is realized, the function of reminding and recording material supplementing is realized, and the problems that the traditional storage bin is low in intelligence and cannot feed back with other components in the paint slag recovery processing technological process in time are solved.

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

Claims

1. Intelligent feed bin based on lacquer sediment recovery processing, including storage silo (1), its characterized in that, the both ends of storage silo (1) are equipped with feeding portion (2) and play hopper (3) respectively, control panel (101) are still installed to the bottom outer end of storage silo (1), control panel (101) electric connection has display screen (102) and start button (103), the bottom mounting that goes out hopper (3) is equipped with discharging pipe (4), feeding portion (2), storage silo (1), play hopper (3) and discharging pipe (4) from the top to the end link up in proper order and connect, feeding portion (2) department installs correct grinding subassembly (5) and sieve separator (7), sieve separator (7) are located under correct grinding subassembly (5), install in going out hopper (3) and finely match subassembly (6);

the precision matching assembly (6) comprises a U-shaped material passing ring plate (601), a U-shaped distribution ring sleeve (602), a U-shaped damping ring sleeve (603), a second servo motor (609) and a fifth rotating rod (610), the bottom end of the U-shaped material passing ring plate (601) is fixedly connected with the bottom end of the discharge hopper (3), the second servo motor (609) is fixedly arranged at the bottom end of the middle part of the U-shaped material passing ring plate (601), the fifth rotating rod (610) is rotatably arranged at the center of the U-shaped material passing ring plate (601), one end of the fifth rotating rod (610) is fixedly connected with an output shaft of the second servo motor (609), the other end of the fifth rotating rod penetrates through the U-shaped material passing ring plate (601) and then is fixedly connected with the U-shaped distribution ring sleeve (602), the U-shaped damping ring sleeve (603) is arranged between the U-shaped distribution ring sleeve (602) and the U-shaped material passing ring plate (601), and the outer end of the U-shaped damping ring sleeve (603) is abutted against the U-shaped distribution ring sleeve (602), the inner end of the U-shaped damping ring sleeve (603) is fixedly sleeved at the outer end of the U-shaped through material ring plate (601), the U-shaped through material ring plate (601) is provided with a plurality of first material passing holes (604), the U-shaped distribution ring sleeve (602) is provided with a plurality of second material passing holes (605), the first material passing holes (604) and the second material passing holes (605) are distributed in an annular array by taking the central axis of the fifth rotating rod (610) as the center of a circle, the first material passing holes (604) are reduced at equal intervals, the U-shaped distribution ring sleeve (602) is provided with a third material passing hole (606), the third material passing hole (606) is movably connected with one first material passing hole (604) in a penetrating way, the bottom end of the U-shaped through material ring plate (601) is arranged on the inner side wall of the discharge hopper (3) and is connected with the discharge hopper in a sliding way, a limiting ring protrusion (608) is fixedly arranged at the bottom end of the U-shaped distribution ring sleeve (602);

the control panel (101) comprises an information acquisition module, a data operation module, a processor, an element execution module and a material supplementing calculation module;

the information acquisition module is used for acquiring working condition environment information and pyrolysis condition information of the material slag in the circulating fluidized bed and sending the information to the data operation module, and also acquiring residual volume information of the paint slag in the storage bin (1) and sending the information to the material supplementing calculation module;

the material supplementing calculation module is used for receiving the residual volume information of the paint slag in the storage bin (1), calculating to obtain a precise material supplementing factor of the bin, comparing the generated precise material supplementing factor of the bin with a preset value, generating a material supplementing early warning prompt signal and sending the material supplementing early warning prompt signal to the element execution module;

the working condition environment information in the circulating fluidized bed collected by the information collection module consists of an air pressure value in a reaction cavity of the circulating fluidized bed, a temperature value in the reaction cavity of the circulating fluidized bed and a temperature value outside the reaction cavity of the circulating fluidized bed, and the pyrolysis condition information of the slag consists of the volume of pyrolysis oil gas and the weight of pyrolysis ash solid;

the data operation module comprises the following specific working steps:

sa: after the data operation module receives the working condition environment information and the pyrolysis condition information of the material slag in the circulating fluidized bed, the air pressure value in the circulating fluidized bed reaction cavity, the temperature value outside the circulating fluidized bed reaction cavity, the volume of pyrolysis oil gas and the weight of pyrolysis ash solid in the circulating fluidized bed reaction cavity are respectively marked as W, E, R, T and Y, and then the pyrolysis oil gas and the pyrolysis ash solid are respectively marked as W, E, R, T and Y according to a formula

Obtaining an intelligent batching factor A of the stock bin; wherein e₁、e₂、e₃、e₄、e₅And e₆Is a weight correction coefficient which enables the calculation result of the intelligent batching factor A of the storage bin to be closer to the true value, and e₂＜e₄＜e₃＜e₅＜e₁＜e₆，e₁+e₂+e₃+e₄+e₅+e₆=17.18；

and (C) Sc: the first accurate batching control signal or the second accurate batching control signal generated in real time is sent to the element execution module through the processor;

the residual volume information of the paint slag in the storage bin (1) collected by the information collection module consists of the total consumption of the paint slag flowing through the refined assembly (6) and the real-time paint slag volume in the storage bin (1);

the concrete working steps of the feed supplement calculation module are as follows:

SSa: the material supplementing calculation module receives the total passing consumption of paint slag flowing through the fine matching assembly (6) and the real-time paint slag volume in the storage bin (1), and respectively marks the total passing consumption and the real-time paint slag volume as U and P according to a formula

Obtaining a precise feed supplement factor B of the stock bin; wherein k is₁、k₂And k₃In order to simulate the correction factor, the result of the calculation of the accurate feed supplement factor B of the storage bin is closer to the true value by the simulated correction factor, and k is₁＞k₃＞k₂，k₁+k₂+k₃=5.16；

SSb: comparing the generated accurate feed supplement factor B of the storage bin with a preset value B, and generating a feed supplement early warning prompt signal when B is less than or equal to B, otherwise, not generating the feed supplement early warning prompt signal;

SSc: and the generated feeding early warning prompt signal is sent to an element execution module.

2. The intelligent storage bin based on paint slag recovery and treatment of claim 1, wherein a guide chute (607) is formed at the outer end of the U-shaped distribution ring sleeve (602), and the guide chute (607) is communicated with the third material passing hole (606).

3. The intelligent storage bin based on paint slag recovery processing according to claim 1, wherein the third material passing hole (606) and the second material passing hole (605) have the same diameter, and the top end of the U-shaped distribution ring sleeve (602) at the connection position with the fifth rotating rod (610) is arc-shaped in cross section.

4. The intelligent silo based on paint slag recovery processing of claim 1, wherein the fine grinding assembly (5) comprises two coarse grinding rollers (501), two first rotating rods (502), two first fine grinding rollers (504), two second rotating rods (505), two second fine grinding rollers (507), a third rotating rod (508) and a first servo motor (511), the coarse grinding rollers (501) are symmetrically arranged, the coarse grinding rollers (501) are mutually meshed and used for crushing the paint slag, the first rotating rods (502) are rotatably connected with the feeding portion (2), the first rotating rods (502) are symmetrically arranged, the outer ends of the first rotating rods (502) are fixedly sleeved with the coarse grinding rollers (501), one end of one first rotating rod (502) extends to the outer portion through the inner wall of the feeding portion (2) and is fixedly sleeved with a first gear (503), the rough grinding roller (501) is arranged right above the first fine grinding roller (504), the first fine grinding roller (504) is abutted to the second fine grinding roller (507), the first fine grinding roller (504) is symmetrically arranged on two sides of the second fine grinding roller (507), the second rotating rod (505) and the third rotating rod (508) are rotatably arranged in the feeding part (2), the second rotating rod (505) is provided with two rotating rods, the second rotating rod (505) is symmetrically arranged on two sides of the third rotating rod (508), the outer ends of the second rotating rod (505) and the third rotating rod (508) are respectively fixedly sleeved with the first fine grinding roller (504) and the second fine grinding roller (507), one end of the second rotating rod (505) penetrates through the inner wall of the feeding part (2) and extends to the outside of the feeding part and is fixedly sleeved with the second gear (506), one end of the third rotating rod (508) penetrates through the inner wall of the feeding part (2) and extends to the outside of the feeding part and is fixedly sleeved with the third gear (509) and the fourth gear (510) The utility model discloses a feeding portion, first servo motor (511) are fixed locates the center department of feeding portion (2) one side, the output shaft fixedly connected with fourth bull stick (512) of first servo motor (511), the fixed fifth gear (513) and sixth gear (514) of having cup jointed of one end of fourth bull stick (512), fifth gear (513) are connected through the gear chain transmission with first gear (503), sixth gear (514) are connected through gear chain and fourth gear (510) transmission, one third gear (509) are connected through gear chain and two second gear (506) transmission.

5. The intelligent storage bin based on paint slag recovery processing according to claim 1, wherein the specific working steps of the element execution module are as follows:

sa: when the element execution module receives the first accurate batching control signal, the accurate batching component (6) is immediately controlled to increase the supply of the paint slag in the reaction cavity of the circulating fluidized bed;

sb: when the second accurate batching control signal is received and generated, the accurate batching component (6) is immediately controlled to reduce the supply of the accurate batching component (6) to the materials;

and (C) Sc: when the element execution module receives the feeding early warning prompt signal, a feeding early warning text is immediately edited and sent to a display screen (102) to be displayed and flicked, wherein the feeding early warning text is that paint slag reaches a use early warning value, and workers are required to accelerate the addition of the paint slag into the storage bin; the feeding early warning text is used for reminding workers of feeding materials in time;

simultaneously, paint slag is immediately added to the feeding part (2), the fine grinding assembly (5) and the sieving device (7) are started, the material storage bin (1) is filled until the material in the material storage bin (1) reaches a preset paint slag volume value, and then the material supplementing early warning text is controlled to stop flashing, and the automatic material supplementing text is edited and displayed on the display screen (102); wherein the automatic feeding text is 'automatically feeding for the nth time', and n is a positive integer.