CN111957716A - Baking-free brick slag building device system - Google Patents

Abstract

The invention relates to a baking-free brick slag building device system, wherein a slag building raw material is firstly initially broken through a jaw crusher, and then is connected with a magnetic drum, a roller screen and a suspended magnet machine through a multi-stage conveyer belt, iron materials magnetically selected enter an iron blasting machine, sand materials enter a sand blasting machine, and the sand materials discharged by the sand blasting machine enter a production line after being subjected to multi-stage screening through the magnetic drum, a titanium jumping machine and a sorting machine; and (3) screening the sand material again from the iron material discharged from the iron knockout machine, and screening the sand material in the iron material again in the titanium jump machine to separate the iron material from the sand material. The invention can fully crush the building slag without damaging the size of the raw garbage. Through multiple grading, the obtained building slag has low water content and less raw materials, and the building slag is more beneficial to comprehensive utilization.

Description

Baking-free brick slag building device system

Technical Field

The invention belongs to the technical field of brick making processes, and particularly relates to a baking-free brick slag building device system.

Background

The baking-free brick is a novel wall material which is manufactured by taking any one or more of fly ash, cinder, coal gangue, tailing slag, chemical slag or natural sand and tidal marsh mud as main raw materials without high-temperature calcination, and is widely applied to the building industry.

The existing slag building process cannot process materials with large particle sizes, the building slag contains slag materials with large particle sizes, equipment is inconvenient for processing the building slag with large particle sizes, wastes such as reinforcing steel bars and the like in the building slag need to be processed, and the existing process cannot be realized.

Disclosure of Invention

The invention aims to solve the problems and provides a baking-free brick slag building device system which can fully separate components in slag. Is a device system capable of separating baking-free bricks and building slag and a device system capable of separating baking-free bricks and slag

And (4) compounding a dual-purpose system.

In order to solve the problems, the technical scheme adopted by the invention is as follows:

a baking-free brick slag building device system is characterized in that jaw crushing is arranged below a hopper, a 1# conveying belt is arranged below the jaw crushing, the 1# conveying belt is connected with a 1# roller screen, a 2# conveying belt is arranged below the 1# roller screen, an upper screen of the 1# roller screen inclines towards the side part, a 3# conveying belt is arranged on the side part of the 1# roller screen, a 4# conveying belt is arranged below the 2# conveying belt and the 3# conveying belt, a 1# suspension magnet machine is arranged behind the 4# conveying belt, the 4# conveying belt is connected with a 5# conveying belt, a 2# suspension magnet machine is arranged behind the 5# conveying belt, a 6# conveying belt is arranged at the side part of the 1# suspension magnet machine and the 2# suspension magnet machine; the No. 5 conveying belt is connected with the No. 1 magnetic roller, the No. 1 magnetic roller is connected with the No. 1 sanding machine and the No. 2 sanding machine, water is injected into the No. 1 sanding machine and the No. 2 sanding machine, and the No. 1 magnetic roller iron discharging channel is connected with the iron sanding machine;

an iron powder channel of the iron forging machine is connected with a 7# conveying belt, the 7# conveying belt is connected with an 8# conveying belt, a 2# magnetic roller is arranged at the front end of the 8# conveying belt, an iron discharging channel of the 2# magnetic roller is connected with the 8# conveying belt, the 8# conveying belt is connected with a 2# roller screen, the 2# roller screen is flushed by water, an iron discharging channel of the 2# roller screen is connected with a 9# conveying belt, and the 9# conveying belt is connected with a coarse iron pile;

the sand discharge channel of the 7# conveying belt is connected with a 3# magnetic roller, the 3# magnetic roller is connected with a 3# titanium jumping machine, the 3# titanium jumping machine is connected with a 4# magnetic roller, the 4# magnetic roller is connected with a first dewatering screen, the first dewatering screen is connected with a 10# conveying belt, and the 10# conveying belt is connected with a sand washing pile;

the 3# titanium hopping machine is connected with a second shaking table, the second shaking table is connected with a sedimentation tank, the sedimentation tank is connected with a second dewatering screen through a water pump, the second dewatering screen is connected with a 10# conveying belt, and the 10# conveying belt is connected with a elutriation stacking area;

the No. 1 sanding machine and the No. 2 sanding machine are connected with the No. 5 magnetic roller and the No. 6 magnetic roller, the No. 5 magnetic roller and the No. 6 magnetic roller are connected with the No. 1 titanium hopping machine and the No. 2 titanium hopping machine, and the iron discharging channels of the No. 5 magnetic roller and the No. 6 magnetic roller are connected with the No. 2 roller screen;

the titanium machine is jumped to 1# jump, the 3# roller screen is connected to the titanium machine is jumped to 2# jump, and the third dewatering screen is connected to the 3# roller screen, and the 11# conveyer belt is connected to the third dewatering screen, and the 1# sorter is connected to the 11# conveyer belt, and the 2# sorter is connected to the 1# sorter, and the 12# conveyer belt is connected to the 2# sorter, and the 4# roller screen is connected the production line to the 12# conveyer belt.

The invention has the beneficial effects that:

(1) the building slag can be fully crushed without damaging the size of the raw materials of the garbage.

(2) Through multiple grading, the slag building amount can be reduced to the maximum extent, the production water consumption is reduced, water is controlled more easily, and the wet, messy and dirty production site is avoided; repeated crushing of the building slag is reduced, dust is reduced, and energy conservation and environmental protection are facilitated; the obtained building slag has low water content and less raw materials, and is more beneficial to comprehensive utilization.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a process flow diagram of a baking-free brick slag building device system according to the present invention;

Detailed Description

The following detailed description of the preferred embodiments of the present invention is provided to enable those skilled in the art to more readily understand the advantages and features of the present invention and to clearly and unequivocally define the scope of the present invention.

A baking-free brick slag building device system comprises a hopper, wherein a jaw crusher is arranged below the hopper, a 1# conveying belt 1 is arranged below the jaw crusher, the 1# conveying belt 1 is connected with a 1# roller screen 2, a 2# conveying belt 3 is arranged below the 1# roller screen 2, an upper screen surface of the 1# roller screen 2 inclines towards the side part, a 3# conveying belt 4 is arranged at the side part of the 1# roller screen 2, a 4# conveying belt 5 is arranged below the 2# conveying belt 3 and the 3# conveying belt 4, a 1# suspended magnet machine 6 is arranged behind the 4# conveying belt 5, the 4# conveying belt 5 is connected with a 5# conveying belt 7, a 2# suspended magnet machine 8 is arranged behind the 5# conveying belt 7, a 6# conveying belt 9 is arranged at the side part of the 1# suspended magnet machine 6 and the 2# suspended magnet machine; the No. 5 conveying belt 7 is connected with a No. 1 magnetic roller 11, the No. 1 magnetic roller 11 is connected with a No. 1 sander 12 and a No. 2 sander 13, the No. 1 sander 12 and the No. 2 sander 13 are filled with water, and the iron discharging channel of the No. 1 magnetic roller 11 is connected with an iron blaster 10.

An iron powder channel of the iron drilling machine 10 is connected with a 7# conveying belt 13, the 7# conveying belt 13 is connected with an 8# conveying belt 14, the front end of the 8# conveying belt 14 is provided with a 2# magnetic roller 15, an iron discharging channel of the 2# magnetic roller 15 is connected with the 8# conveying belt 14, the 8# conveying belt 14 is connected with a 2# roller screen 16, the 2# roller screen 16 is flushed with water, an iron discharging channel of the 2# roller screen 16 is connected with a 9# conveying belt 17, and the 9# conveying belt 17 is connected with a coarse iron pile 18.

The sand discharge channel of the 7# conveyor belt 13 is connected with a 3# magnetic roller 19, the 3# magnetic roller 19 is connected with a 3# titanium jumping machine 20, the 3# titanium jumping machine 20 is connected with a 4# magnetic roller 21, the 4# magnetic roller 21 is connected with a first dewatering screen 22, the first dewatering screen 22 is connected with a 10# conveyor belt 23, and the 10# conveyor belt 23 is connected with a sand washing pile 24.

The 3# titanium hopping machine 20 is connected with a second shaking table 25, the second shaking table 25 is connected with a sedimentation tank 26, the sedimentation tank 26 is connected with a second dewatering screen 27 through a water pump, the second dewatering screen 27 is connected with a 10# conveying belt 23, and the 10# conveying belt 23 is connected with a elutriation stacking area 24.

The No. 1 sander 12 and the No. 2 sander 13 are connected with the No. 5 magnetic roller 31 and the No. 6 magnetic roller 32, the No. 5 magnetic roller 31 and the No. 6 magnetic roller 32 are connected with the No. 1 titanium jumping machine 33 and the No. 2 titanium jumping machine 34, and the iron discharging channels of the No. 5 magnetic roller 31 and the No. 6 magnetic roller 32 are connected with the No. 2 roller screen 16.

The # 1 titanium hopping machine 33 and the # 2 titanium hopping machine 34 are connected with a # 3 rolling screen 37, the # 3 rolling screen 37 is connected with a third dewatering screen 38, the third dewatering screen 38 is connected with a # 11 conveying belt 39, the # 11 conveying belt 39 is connected with a # 1 sorting machine 40, the # 1 sorting machine 40 is connected with a # 2 sorting machine 41, the # 2 sorting machine 41 is connected with a # 12 conveying belt 42, the # 12 conveying belt 42 is connected with a # 4 rolling screen 43, and the # 4 rolling screen 43 is connected with the production line.

The specific process flow for this specific example is described as follows:

the raw materials are sent into a hopper by a loader, slide into a jaw crusher through a hopper chute to be initially broken, and are conveyed to a No. 1 conveying belt by a lower conveying belt after the jaw crusher is initially broken, and then are sent into a No. 1 roller screen. The small granules fall from the No. 1 sieve holes onto the No. 2 conveyor belt below the No. 1 roller sieve. The upper screen surface of the No. 1 roller screen inclines towards the side part, and large granular materials slide into a No. 3 conveying belt on the side part of the No. 1 roller screen from the upper screen surface of the No. 1 roller screen. The transmission speed of the 2# conveyer belt is higher than that of the 3# conveyer belt, and the small granules on the 2# conveyer belt are transmitted to the 4# conveyer belt before the large granules on the 3# conveyer belt, so that the large granules on the 4# conveyer belt are beneficial to the iron absorption of the following 1# suspended magnet machine. The 4# conveyer belt realizes the material upset when reaching 5# conveyer belt with the material, does benefit to 2# and hangs magnet machine and inhale the iron once more. A No. 1 suspension magnet machine is arranged on the No. 4 conveying belt, a No. 2 suspension magnet machine is arranged on the No. 5 conveying belt, and iron-absorbing materials of the No. 1 suspension magnet machine and the No. 2 suspension magnet machine are simultaneously fed into the No. 6 conveying belt which is erected in parallel with the No. 5 conveying belt. The iron material is sent into the iron knockout machine by a No. 6 conveyer belt. The sand material that leaves behind the 1# suspended magnet machine, the 2# suspended magnet machine magnet attraction is continued to be sent up by 5# conveyer belt, and after the sand material is located the terminal 1# magnetic drum of 5# conveyer belt magnet once more, the reposition of redundant personnel gets into 1# sanding machine, 2# sanding machine through the diverging device reposition of redundant personnel to the water injection. The iron material absorbed by the 1# magnetic roller and the 6# conveying belt iron material enter the iron forging machine through the slideway.

The iron material crushed by the iron crusher is output by a 7# conveying belt and passes through an 8# conveying belt erected on the upper part of the 7# conveying belt. The 2# magnetic roller at the front end of the 8# conveying belt absorbs iron, and the absorbed iron is conveyed into the 2# roller screen by the 8# conveying belt to be flushed with water. And then the iron is conveyed to a coarse iron stacking area by a No. 9 conveying belt.

The sand material conveyed by the 7# conveying belt enters the slideway, after the iron powder is absorbed by the 3# magnetic roller, the iron powder is flushed into the special slideway by water and is conveyed to the iron powder stacking area, and the sand material enters the 3# titanium hopping machine. After passing through a 3# titanium jump machine, the fine iron powder is absorbed by a 4# magnetic roller, the fine iron powder is flushed into a special slideway by water to enter a hopper car for transportation, and sand materials enter a channel below a small dewatering screen to enter a large dewatering screen for dewatering and sand washing. The sand is conveyed to a sand washing and stacking area by a No. 10 conveyer belt.

Sand materials flushed from two water outlets below the 3# titanium hopping machine pass through the channel and go to the shaking table. And (4) separating fine iron powder and copper sand by a shaking table, and pumping the water with the sand into a settling tank and a water pump into a large dewatering screen.

And feeding the sand material of the two sand blasting machines by the 5# conveying belt, and after crushing, sucking iron by a 5# magnetic roller and a 6# magnetic roller which are arranged at the outlet of the sand blasting machine, and then feeding the crushed sand material into the 1# titanium jump machine and the 2# titanium jump machine. And the iron sucked by the 5# magnetic roller and the 6# magnetic roller enters the 2# roller screen through the slide way and is conveyed to a coarse iron stacking area together with iron materials of the iron beater through a 9# conveyor belt.

The sand material flushed from four water outlets below the No. 1 titanium tripping machine and the No. 2 titanium tripping machine is converged and flows into the No. 3 titanium tripping machine through a channel. And sand materials passing through the No. 1 titanium hopping machine and the No. 2 titanium hopping machine are converged into a special channel after titanium hopping and enter a No. 3 roller screen. The water carries the elutriation sand through the sieve holes and falls into the channel leading to the large dewatering sieve. Large-particle materials are rolled out from the tail part of the 3# roller screen and enter a small dewatering screen, and are conveyed into the 1# sorting machine through the 11# conveying belt after being dewatered, and are conveyed into the 4# roller screen through the 12# conveying belt after entering the 2# sorting machine. The elutriated grains are rolled out through the sieve pores. The uncrushed materials are rolled out from an outlet of the 4# roller screen, and the materials are separated from the garbage area and then enter the production line.

The aluminium that 1# sorter was elected falls into and connects the aluminium storage bucket, and the aluminium that 2# sorter was elected falls into and connects the aluminium trolley, transports to sunning dam sunning back secondary selection aluminium.

All water used for production is recycled to a large dewatering screen sedimentation tank by a recycling system, is sent to a water storage tank by two 45kw water pumps, and is sent to four filter presses by four 55kw rotary pumps to complete mud pressing. The clean water filtered by the pressing plate flows into a clean water tank through a pipeline and is pumped to each point of the production line by two pressurized water pumps for recycling.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, that the preferred embodiments of the present invention are described above and the present invention is not limited to the preferred embodiments, and that various changes and modifications may be made without departing from the spirit and scope of the present invention and these changes and modifications are within the scope of the invention as claimed.

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

Claims (1)

1. A baking-free brick slag building device system is characterized in that a jaw crusher is arranged below a hopper, a 1# conveying belt is arranged below the jaw crusher, the 1# conveying belt is connected with a 1# roller screen, a 2# conveying belt is arranged below the 1# roller screen, an upper screen surface of the 1# roller screen inclines towards the side portion, a 3# conveying belt is arranged on the side portion of the 1# roller screen, a 4# conveying belt is arranged below the 2# conveying belt and the 3# conveying belt, a 1# suspended magnet machine is arranged behind the 4# conveying belt, the 4# conveying belt is connected with a 5# conveying belt, a 2# suspended magnet machine is arranged behind the 5# conveying belt, a 6# conveying belt is arranged at the side portion of the 1# suspended magnet machine and the 2# suspended magnet machine, and; the No. 5 conveying belt is connected with the No. 1 magnetic roller, the No. 1 magnetic roller is connected with the No. 1 sanding machine and the No. 2 sanding machine, water is injected into the No. 1 sanding machine and the No. 2 sanding machine, and the No. 1 magnetic roller iron discharging channel is connected with the iron sanding machine;

an iron powder channel of the iron forging machine is connected with a 7# conveying belt, the 7# conveying belt is connected with an 8# conveying belt, a 2# magnetic roller is arranged at the front end of the 8# conveying belt, an iron discharging channel of the 2# magnetic roller is connected with the 8# conveying belt, the 8# conveying belt is connected with a 2# roller screen, the 2# roller screen is flushed by water, an iron discharging channel of the 2# roller screen is connected with a 9# conveying belt, and the 9# conveying belt is connected with a coarse iron pile;

the sand discharge channel of the 7# conveying belt is connected with a 3# magnetic roller, the 3# magnetic roller is connected with a 3# titanium jumping machine, the 3# titanium jumping machine is connected with a 4# magnetic roller, the 4# magnetic roller is connected with a first dewatering screen, the first dewatering screen is connected with a 10# conveying belt, and the 10# conveying belt is connected with a sand washing pile;

the 3# titanium hopping machine is connected with a second shaking table, the second shaking table is connected with a sedimentation tank, the sedimentation tank is connected with a second dewatering screen through a water pump, the second dewatering screen is connected with a 10# conveying belt, and the 10# conveying belt is connected with a elutriation stacking area;

the No. 1 sanding machine and the No. 2 sanding machine are connected with the No. 5 magnetic roller and the No. 6 magnetic roller, the No. 5 magnetic roller and the No. 6 magnetic roller are connected with the No. 1 titanium hopping machine and the No. 2 titanium hopping machine, and the iron discharging channels of the No. 5 magnetic roller and the No. 6 magnetic roller are connected with the No. 2 roller screen;

the titanium machine is jumped to 1# jump, the 3# roller screen is connected to the titanium machine is jumped to 2# jump, and the third dewatering screen is connected to the 3# roller screen, and the 11# conveyer belt is connected to the third dewatering screen, and the 1# sorter is connected to the 11# conveyer belt, and the 2# sorter is connected to the 1# sorter, and the 12# conveyer belt is connected to the 2# sorter, and the 4# roller screen is connected the production line to the 12# conveyer belt.

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