CN112430121A

CN112430121A - Production process of environment-friendly light non-clay brick

Info

Publication number: CN112430121A
Application number: CN202011168704.1A
Authority: CN
Inventors: 吴忠贤; 张明德; 郑文炯; 朱义沉
Original assignee: Fujian Nan'an Yingsheng New Wall Material Co ltd
Current assignee: Fujian Nan'an Yingsheng New Wall Material Co ltd
Priority date: 2020-10-28
Filing date: 2020-10-28
Publication date: 2021-03-02
Anticipated expiration: 2040-10-28
Also published as: CN112430121B

Abstract

The invention discloses a production process of an environment-friendly light non-clay brick, which comprises the following steps: firstly, collecting waste soil uniformly; crushing the waste soil by a crushing and screening device and screening and removing metal residues mixed in the waste soil; thirdly, carrying out box separation and storage on the waste soil particles in the waste soil collecting box through a storage box; fourthly, conveying the plurality of storage boxes to the basement for fermentation; removing bubbles in the storage box through a foam removing device; sixthly, pouring the fermented waste soil into an extruder, and extruding the waste soil into bricks through the extruder; seventhly, drying; eighthly, drying; ninthly, sintering. The scheme not only effectively avoids the explosion accident of the building rubbish in the later sintering process, but also can prevent organic matters from generating air holes in the sintering process, so that the safe and high-quality production of the bricks is realized.

Description

Production process of environment-friendly light non-clay brick

Technical Field

The invention relates to an environment-friendly light non-clay production process.

Background

Along with the acceleration of our modernization construction pace, the waste soil such as saw mud, mountain flour of panel factory increases day by day, consequently in order to effective cyclic utilization these waste soil, utilize waste soil to replace clay, produce baked brick, both can avoid the waste of waste soil, still realize the sustainable development of brick and tile factory.

However, the waste soil is mixed with more organic matters relative to clay, the organic matters can be combusted during the sintering of the brick, the combustion process easily causes explosion and air holes, potential safety hazards exist, and the quality of the brick is also influenced.

In view of the above, the applicant has made an intensive study to solve the above problems and has made the present invention.

Disclosure of Invention

The invention mainly aims to provide an environment-friendly light non-clay production process, which ensures safe and high-quality production.

In order to achieve the above purpose, the solution of the invention is:

provides a production process of an environment-friendly light non-clay brick, which comprises the following steps:

firstly, collecting waste soil uniformly;

crushing the waste soil through a crushing and screening device and screening and removing metal residues mixed in the waste soil: the crushing and screening device comprises a crusher, a guide plate, a magnetic roller, a scraping plate, a metal collecting box and a waste soil collecting box, wherein the crusher comprises two crushing rollers, the guide plate is arranged below the two crushing rollers, one end of the guide plate extends towards the magnetic roller, the metal collecting box is arranged below the magnetic roller, the waste soil collecting box is arranged beside the side of the magnetic roller, waste soil is crushed by the two crushing rollers to form waste soil particles, the waste soil particles fall to the guide plate from between the two crushing rollers and are guided to fall to the surface of the magnetic roller by the guide plate, the magnetic roller adsorbs the metal particles, the metal particles adsorbed on the surface of the magnetic roller are scraped to fall into the metal collecting box by the scraping plate in the rolling process of the magnetic roller, and the waste soil particles fall into the waste soil collecting box under the rolling guide of the magnetic roller;

thirdly, carrying out box separation and storage on the waste soil particles in the waste soil collecting box through a storage box;

fourthly, conveying a plurality of storage boxes to the basement for fermentation: the basement is internally provided with three vertically-arranged oval conveying tracks which are arranged at equal intervals along the direction of a short axis, the basement is provided with an inlet and an outlet, a plurality of box containing boxes enter the three oval conveying tracks one by one from the inlet of the basement and are conveyed by the three oval conveying tracks and then are output one by one from the outlet of the basement, the containing boxes are transferred on the two adjacent oval conveying tracks through a transfer device, and the conveying time of the containing boxes on the three oval conveying tracks is equal to the fermentation time of the waste soil;

removing bubbles in the storage box through a foam removing device;

sixthly, pouring the fermented waste soil into an extruder, and extruding the waste soil into bricks through the extruder;

seventhly, drying;

eighthly, drying;

ninthly, sintering.

Further, the crusher comprises a support, a rotating shaft, a vibrator, a telescopic rod and a spring, wherein the rotating shaft is supported on the support, the rotating shaft supports the crushing roller, the telescopic rod penetrates through the spring, then the two ends of the telescopic rod are respectively connected with the vibrator and the support, and the two ends of the spring are abutted against the support and the vibrator.

Furthermore, the transfer device comprises a first inductor, a second inductor, a third inductor, a fourth inductor, a fifth inductor, a sixth inductor, a seventh inductor, clamping tracks, a plurality of movable clamps, a sensor and a controller, wherein the movable clamps, the sensor and the controller are arranged in a one-to-one correspondence manner, the containing box is divided into a first side edge and a second side edge in the arrangement direction of the three oval conveying tracks, the conveying directions of the two adjacent oval conveying tracks are opposite, the first inductor is arranged at the entrance of the basement, the second inductor and the third inductor are oppositely arranged and are arranged between the two adjacent oval conveying tracks, the fourth inductor and the fifth inductor are oppositely arranged and are arranged between the other two adjacent oval conveying tracks, the sixth inductor and the seventh inductor are oppositely arranged and are arranged at the exit of the basement, and the clamping tracks are fixed at the outer sides of the oval conveying tracks, the movable clamp, the sensor and the controller are arranged on the first side edge and the second side edge, the sensor is electrically connected with the input end of the controller, and the movable clamp is electrically connected with the output end of the controller.

Furthermore, the foam removing device is arranged at the outlet of the basement and comprises a translation cylinder, a lifting cylinder, a vacuum adsorption machine and a vacuum adsorption frame, the translation cylinder drives the vacuum adsorption machine to move back and forth, the lifting cylinder drives the vacuum adsorption frame to lift, and the vacuum adsorption frame is arranged at the outlet of the vacuum adsorption machine and aligned with the opening of the storage box.

After the structure is adopted, the production process of the environment-friendly light non-clay brick has the beneficial effects that the crushing and screening device is used for crushing and quickly screening the waste soil to remove metal residues in the waste soil, and the waste soil is fermented in the basement, so that organic matters in the waste soil are converted into inorganic matters, the explosion accident of building garbage in the later sintering process can be effectively avoided, air holes of the organic matters in the sintering process can be prevented, and the brick can be safely and high-quality produced.

Drawings

FIG. 1 is a schematic view of the overall structure of the present disclosure;

FIG. 2 is a top view of the present disclosure;

FIG. 3 is a partially enlarged schematic view of the present disclosure;

FIG. 4 is a schematic diagram showing the combination of the magnetic roller, the scraper, the metal collecting box and the waste soil collecting box;

FIG. 5 is a cross-sectional view of FIG. 4;

FIG. 6 is a schematic structural diagram of the crusher of the present disclosure;

fig. 7 is a schematic structural view of the foam removing device of the present disclosure.

In the figure:

crushing and screening device-100, crusher-110, crushing roller-111, support-112, rotating shaft-113, vibrator-114, spring-115, guide plate-120, magnetic roller-130, scraper-140, metal collecting box-150 and waste soil collecting box-160;

a foam removing device-200, a vacuum adsorption machine-210 and a vacuum adsorption frame-220;

container-300, first side-310, second side-320;

an elliptical delivery track-400;

output track-500;

the device comprises a transfer device-600, a first inductor-601, a second inductor-602, a third inductor-603, a fourth inductor-604, a fifth inductor-605, a sixth inductor-606, a seventh inductor-607, a clamping track-608, a movable clamp-609, a sensor-610 and a controller-611.

Detailed Description

In order to further explain the technical solution of the present invention, the present invention is explained in detail by the following specific examples.

As shown in fig. 1-7, the present application provides a process for producing an environment-friendly light non-clay brick, which comprises the following steps:

firstly, waste soil is collected uniformly, and the waste soil is preferably waste soil such as saw mud, stone powder and the like of a plate factory.

Crushing the waste soil by the crushing and screening device 100 and screening and removing metal residues mixed in the waste soil: the crushing and screening apparatus 100 includes a crusher 110, a guide plate 120, a magnetic drum 130, a scraper 140, a metal collecting box 150, and a waste soil collecting box 160. The crusher 110 includes two crushing rollers 111, a guide plate 120 is disposed below the two crushing rollers 111, one end of the guide plate 120 extends toward the magnetic roller 130, the metal collection box 150 is disposed below the magnetic roller 130, the waste soil collection tank is disposed beside the magnetic roller 130, waste soil is crushed by the two crushing rollers 111 to form waste soil particles, the waste soil particles fall between the two crushing rollers 111 to the guide plate 120 and fall onto the surface of the magnetic roller 130 through the guide plate 120, the magnetic roller 130 adsorbs the metal particles, the metal particles adsorbed on the surface of the magnetic roller 130 are scraped into the metal collection box 150 by the scraper 140 during the rolling process of the magnetic roller 130, and the waste soil particles fall into the waste soil collection box 160 under the rolling guide of the magnetic roller 130.

Thirdly, the waste soil particles in the waste soil collecting box 160 are collected in separate boxes through the collecting box 300.

Fourthly, conveying the plurality of storage boxes 300 to the basement for fermentation: be equipped with three oval delivery track of putting immediately in the basement, three oval delivery track are along equidistant range of minor axis direction, the basement is equipped with entry and export, a plurality of casees containing box 300 get into three oval delivery track one by one from the entry of basement to export from the basement one by one after three oval delivery track are carried, containing box 300 passes through transfer device 600 and shifts at two adjacent oval delivery track, containing box 300 is equal with the fermentation time of abandonment soil at three oval delivery track's transport time. From this, the present case makes transport time unanimous with fermentation time through design oval delivery track's length and its conveying speed, and the discarded soil is carried the fermentation while in the basement promptly, and when containing box 300 carried the output to the export of basement from the entry of basement, the discarded soil just in time ferments and accomplishes to through carrying one by one, thereby realize continuous transport, process steps about linking up in order, make whole technology keep the continuity, avoid spending too much latency, realize more efficient production. The oval conveying track can ensure that the track can be distributed in the basement as much as possible, thereby fully utilizing the space of the basement.

Removing bubbles inside the receiving box 300 through the foam removing apparatus 200.

Sixthly, pouring the fermented waste soil into an extruder, and extruding the waste soil through the extruder to prepare the brick.

And drying in the air.

And (8) drying.

Ninthly, sintering.

Therefore, the crushing and screening device 100 is used for crushing and rapidly screening the waste soil to remove metal residues in the waste soil, and fermenting the waste soil through the underground chamber, so that organic matters in the waste soil are converted into inorganic matters, the building waste is effectively prevented from being exploded accidentally in the later sintering process, air holes can be prevented from being generated in the organic matter sintering process, and safe and high-quality production is realized.

As a specific embodiment of the crusher 110 in the present disclosure, preferably, the crusher 110 includes a bracket 112, a rotating shaft 113, a vibrator 114, a telescopic rod and a spring 115, the rotating shaft 113 is supported on the bracket 112, the rotating shaft 113 supports the crushing roller 111, two ends of the telescopic rod, after passing through the spring 115, are respectively connected to the vibrator 114 and the bracket 112, and two ends of the spring 115 press against the bracket 112 and the vibrator 114 to provide elastic pressure for the two. Under the cooperation of the elastic force of the spring 115 and the high-speed vibration of the vibrator 114, the telescopic rod can stretch and retract back and forth, the two crushing rollers 111 generate opposite impact force under the action of the high-speed vibrator 114, and waste soil is further crushed, so that the crushing is more uniform.

The transfer device 600 is used for changing the conveying track of the container 300, and as a specific embodiment of the transfer device 600 in the present disclosure, preferably, the transfer device 600 includes a first inductor 601, a second inductor 602, a third inductor 603, a fourth inductor 604, a fifth inductor 605, a sixth inductor 606, a seventh inductor 607, a clamping track 608, a plurality of movable clamps 609, sensors 610 and controllers 611, which are arranged in a one-to-one correspondence manner, and one controller 611 receives one sensor 610. The containing box 300 is divided into a first side 310 and a second side 320 in the arrangement direction of the three oval conveying tracks, the conveying directions of the two adjacent oval conveying tracks are opposite, a first inductor 601 is arranged at an entrance of the basement, a second inductor 602 and a third inductor 603 are oppositely arranged and arranged between the two adjacent oval conveying tracks, a fourth inductor 604 and a fifth inductor 605 are oppositely arranged and arranged between the other two adjacent oval conveying tracks, and the second inductor 602, the third inductor 603, the fourth inductor 604 and the fifth inductor 605 are arranged at the corner positions of the oval conveying tracks. Sixth inductor 606 and seventh inductor 607 set up and establish in the exit of basement relatively, centre gripping track 608 is fixed in the oval delivery track outside, and six inductors all establish in oval delivery track top, and specific accessible shelf is unsettled to erect, activity clamp 609, sensor 610 and controller 611 establish first side 310 and second side 320, first side 310 and second side 320 all are equipped with two activity clamps 609, sensor 610 and controller 611, can make containing box 300 carry more steadily, and sensor 610 is connected with the input electricity of controller 611, and activity clamp 609 is connected with the output electricity of controller 611.

The transfer device 600 further comprises an output track 500, a clamping track 608 is also arranged on the output track 500, and the working principle of the transfer device 600 is as follows: firstly, the movable clamp 609 on the first side 310 is clamped on the clamping track 608, the container 300 is moved, when the container 300 moves to the first sensor 601, the sensor 610 on the first side 310 senses the first sensor 601 and transmits a signal to the controller 611, the controller 611 receives the signal from the sensor 610 and controls the movable clamp 609 to clamp the clamping track 608, so that the container 300 and the clamping track 608 move synchronously, thereby driving the container 300 to move through the oval conveying track, when the container 300 moves to the second sensor 602 and the third sensor 603, the sensor 610 on the first side 310 senses the second sensor 602 and senses the third sensor 603, the controllers 611 on the first side 310 and the second side 320 respectively control the movable clamps 609 on the two sides, specifically, the movable clamp 609 on the first side 310 loosens the clamping track 608, similarly, when the containing box 300 is conveyed to the fourth inductor 604 and the fifth inductor 605, the movable clamp 609 at the second side 320 loosens the clamping track 608, the movable clamp 609 at the first side 310 tightens the clamping track 608, the oval conveying track near the exit of the basement drives the containing box 300 to convey, when the containing box 300 is conveyed to the sixth inductor 606 and the seventh inductor 607, the movable clamp 609 at the first side 310 loosens the clamping track 608, the movable clamp 609 at the second side 320 clamps the clamping track 608 of the output track 500, and the containing box 300 is conveyed out of the basement by the output track 500. Thereby realizing that the containing box 300 is continuously conveyed on three oval conveying tracks through the transfer device 600. The direction indicated by the arrow in the figure is the conveying direction of each conveying track.

As a specific embodiment of the foam removing device 200, preferably, the foam removing device 200 is disposed at an outlet of a basement and the foam removing device 200 includes a translation cylinder, a vacuum adsorption machine 210 and a vacuum adsorption frame 220, the translation cylinder drives the vacuum adsorption machine 210 to move back and forth, the lifting cylinder drives the vacuum adsorption frame 220 to lift, and the vacuum adsorption frame 220 is disposed at an outlet of the vacuum adsorption machine 210 and aligned with an opening of the storage box 300. The specific process of foam removal is as follows: carry to vacuum adsorption frame 220 under when containing box 300, vacuum adsorption frame 220 descends through the lift cylinder drive, vacuum adsorption frame 220's bottom and the laminating of abandonment soil surface this moment, will arrange in the inside bubble of abandonment soil through vacuum environment and adsorb to abandonment soil surface, then absorb frame 220 translation through translation cylinder drive vacuum, the translation in-process is through vacuum adsorption frame 220 bottom scraping the bubble on abandonment soil surface, realize the high-efficient bubble of getting rid of through ingenious structure and detaining in the inside of abandonment soil from this.

The above embodiments and drawings are not intended to limit the form and style of the present invention, and any suitable changes or modifications thereof by those skilled in the art should be considered as not departing from the scope of the present invention.

Claims

1. The production process of the environment-friendly light non-clay brick is characterized by comprising the following steps:

firstly, collecting waste soil uniformly;

removing bubbles in the storage box through a foam removing device;

seventhly, drying;

eighthly, drying;

ninthly, sintering.

2. The process for producing environment-friendly light non-clay bricks according to claim 1, wherein the crusher comprises a support, a rotating shaft, a vibrator, a telescopic rod and a spring, the rotating shaft is supported on the support, the rotating shaft supports the crushing roller, the telescopic rod is respectively connected with the vibrator and the support at two ends after penetrating through the spring, and two ends of the spring are pressed against the support and the vibrator.

3. The process for producing environment-friendly light non-clay bricks as claimed in claim 1, wherein the transfer device comprises a first sensor, a second sensor, a third sensor, a fourth sensor, a fifth sensor, a sixth sensor, a seventh sensor, a clamping track, a plurality of movable clips, sensors and controllers, the movable clips, the sensors and the controllers are arranged in a one-to-one correspondence manner, the containing box is divided into a first side edge and a second side edge in the arrangement direction of three oval conveying tracks, the conveying directions of two adjacent oval conveying tracks are opposite, the first sensor is arranged at the entrance of the basement, the second sensor and the third sensor are arranged oppositely and arranged between two adjacent oval conveying tracks, the fourth sensor and the fifth sensor are arranged oppositely and arranged between the other two adjacent oval conveying tracks, the sixth sensor and the seventh sensor are arranged oppositely and arranged at the exit of the basement, the clamping track is fixed on the outer side of the oval conveying track, the movable clamp, the sensor and the controller are arranged on the first side edge and the second side edge, the sensor is electrically connected with the input end of the controller, and the movable clamp is electrically connected with the output end of the controller.

4. The process for producing environment-friendly light-weight non-clay brick as claimed in claim 1, wherein the foam removing device is arranged at the outlet position of the basement and comprises a translation cylinder, a lifting cylinder, a vacuum adsorption machine and a vacuum adsorption frame, the translation cylinder drives the vacuum adsorption machine to move back and forth, the lifting cylinder drives the vacuum adsorption frame to lift, and the vacuum adsorption frame is arranged at the outlet position of the vacuum adsorption machine and aligned with the opening of the storage box.