CN215541667U - Slag micro powder processing mechanism convenient for slag loading - Google Patents

Abstract

The utility model relates to a slag micro-powder processing mechanism convenient for slag loading, which comprises a slag micro-powder mill and a bucket elevator, wherein a loading mechanism is arranged on the left surface of the bucket elevator, the loading mechanism comprises an outer shell, a first conveying belt and a second conveying belt are fixedly arranged in the outer shell, and a crusher positioned between the first conveying belt and the second conveying belt is fixedly arranged in the outer shell. This slay miropowder processing mechanism convenient to slay material loading, through screening the processing to the slay before the breakage, make wherein tiny particle slay need not through broken process, directly carry to bucket elevator, it is extravagant to reduce time, and large granule slay then carries to the breaker breakage through the second conveyer belt, then the rethread first conveyer belt carries to bucket elevator, wherein screen the subassembly also can play the additional action when large granule slay is carried, a machine is multi-purpose, and equipment cost is reduced, thereby the problem of the current slay miropowder processing mechanism material loading of not being convenient for has been solved.

Description

Slag micro powder processing mechanism convenient for slag loading

Technical Field

The utility model relates to the technical field of slag micro powder processing, in particular to a slag micro powder processing mechanism convenient for slag loading.

Background

At present, slag plays an important role in industrial production in China, and particularly in some heavy and large factories, the slag is known to be residue of ore after mineral separation or smelting, a plurality of iron and steel enterprises can adopt a vertical grinding machine to grind the slag, and the slag is made into slag cement, slag micro powder, slag portland cement and the like through refining and processing, so that the secondary utilization of the mineral can be realized, and the pollution to the environment can be reduced.

The slag micropowder is a powdery product obtained by ultrafine grinding water-quenched slag discharged from an iron-making blast furnace.

Prepare the slay miropowder in pouring the slay into the milling machine, and present milling machine need carry out broken pretreatment to the slay before the material loading, but because part slay has been the tiny particle slay, need not to carry out the breakage, causes unnecessary operation, influences the material loading efficiency of slay.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides the slag micro-powder processing mechanism convenient for slag loading, which has the advantage of convenience in loading and solves the problem of inconvenience in loading.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a slay miropowder processing mechanism convenient to slay material loading, includes slay miropowder mill and bucket elevator, the bucket elevator left surface is equipped with feed mechanism.

Feed mechanism includes the shell body, fixed mounting has first conveyer belt and second conveyer belt in the shell body, fixed mounting has the breaker that is located between first conveyer belt and the second conveyer belt in the shell body, fixed surface is connected with down the hopper on the shell body, fixed mounting has the partition panel in the hopper down, the partition panel internal rotation is connected with automatically controlled door, fixed mounting has the unloading pipe that is located the second conveyer belt right side in the shell body, the intraductal fixed mounting of unloading has the screening subassembly.

Further, the feed inlet of slay micronizer is linked together with the discharge gate of bucket elevator, set up the treatment chamber in the shell body, first conveyer belt, second conveyer belt, breaker and unloading pipe all with treatment chamber front and back two fixed surface be connected.

Further, first conveyer belt is located second conveyer belt bottom, the direction of rotation of first conveyer belt is clockwise rotation, the direction of rotation of second conveyer belt is anticlockwise rotation, second conveyer belt left surface is located directly over the breaker feed inlet.

Further, the breaker discharge gate is located first conveyer belt top, shell body lower surface fixedly connected with arranges the material pipe that is linked together with the bucket elevator feed inlet, first conveyer belt right side surface is located and arranges directly over the material pipe.

Further, the feeding hole has been seted up to lower hopper upper surface, two fixed surface are connected around partition panel and the feeding hole, the intercommunicating pore has been seted up to partition panel left surface, intercommunicating pore lower surface and partition panel lower surface parallel and level, two surfaces rotate around electrically controlled door and the intercommunicating pore and are connected.

Further, fixed mounting has step motor in the partition panel, step motor's output shaft and automatically controlled door's pivot fixed connection, the water conservancy diversion hole that is linked together and is located directly over the second conveyer belt with the material loading hole is seted up to the shell body upper surface.

Further, unloading pipe upper surface and shell body upper surface parallel and level, the unloading pipe is located directly over the first conveyer belt, the unloading hole has been seted up to unloading pipe upper surface, the equal fixedly connected with deflector of mutual staggered arrangement in both surfaces about the unloading hole.

Further, the screening subassembly includes the screening board, screening board lower fixed surface is connected with quantity is four springs, spring lower fixed surface is connected with the mount pad, mount pad and the downthehole perisporium fixed connection of unloading, fixed surface is connected with the electro-magnet on the mount pad, screening board lower fixed surface is connected with the magnetic path that is located directly over the electro-magnet.

Compared with the prior art, the technical scheme of the application has the following beneficial effects:

this slay miropowder processing mechanism convenient to slay material loading, through screening the processing to the slay before the breakage, make wherein tiny particle slay need not through broken process, directly carry to bucket elevator, it is extravagant to reduce time, and large granule slay then carries to the breaker breakage through the second conveyer belt, then the rethread first conveyer belt carries to bucket elevator, wherein screen the subassembly also can play the additional action when large granule slay is carried, a machine is multi-purpose, and equipment cost is reduced, thereby the problem of the current slay miropowder processing mechanism material loading of not being convenient for has been solved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of a feeding mechanism of the present invention;

FIG. 3 is a schematic view of a connection structure of a partition board and an electric control door according to the present invention;

figure 4 is a schematic structural view of a screening assembly of the present invention.

In the figure: 1 slag micronizer, 2 bucket elevator, 3 feeding mechanism, 31 outer shell, 32 first conveyer belt, 33 second conveyer belt, 34 crusher, 35 blanking hopper, 36 partition board, 37 electric control door, 38 blanking pipe, 4 screening assembly, 41 screening board, 42 spring, 43 mounting seat, 44 electromagnet, 45 magnet.

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. 1-4, the slag micropowder processing mechanism for conveniently feeding slag in the embodiment includes a slag micronizer 1 and a bucket elevator 2, the bucket elevator 2 is located at the left side of the slag micronizer 1, and the left surface of the bucket elevator 2 is movably connected with a feeding mechanism 3.

The feeding mechanism 3 comprises an outer shell 31, a first conveying belt 32 and a second conveying belt 33 are fixedly installed in the outer shell 31, the first conveying belt 32 is located at the bottom of the second conveying belt 33, the rotating direction of a belt of the first conveying belt 32 is clockwise rotation, the rotating direction of a belt of the second conveying belt 33 is counterclockwise rotation, a crusher 34 located between the first conveying belt 32 and the second conveying belt 33 is fixedly installed in the outer shell 31, a blanking hopper 35 is fixedly connected to the upper surface of the outer shell 31, a feeding hole is formed in the upper surface of the blanking hopper 35, a partition plate 36 is fixedly installed in the blanking hopper 35, the partition plate 36 is fixedly connected with the front surface and the rear surface of the feeding hole, a communication hole is formed in the left surface of the partition plate 36, the lower surface of the communication hole is flush with the lower surface of the partition plate 36, an electric control door 37 is rotatably connected with the front surface and the rear surface of the communication hole, and a stepping motor is fixedly installed in the partition plate 36, step motor's output shaft and automatically controlled door 37's pivot fixed connection, shell body 31 upper surface is seted up and is linked together with the material loading hole and is located the water conservancy diversion hole directly over second conveyer belt 33, fixed mounting has the unloading pipe 38 that is located second conveyer belt 33 right side in the shell body 31, fixed mounting has screening subassembly 4 in the unloading pipe 38, utilize the forklift to shovel the slay down in hopper 35, and empty along partition panel 36 right side, make the slay pour into and filter on screening subassembly 4, the slay of large granule is intercepted, and the granule slay falls to first conveyer belt 32 top along unloading pipe 38, then carry to slay micro mill 1 through bucket elevator 2.

It should be noted that, the feed inlet of slay micronizer 1 is linked together with the discharge gate of bucket elevator 2, a treatment chamber is opened in shell 31, first conveyer belt 32, second conveyer belt 33, breaker 34 and unloading pipe 38 all are connected with the front and back two fixed surfaces of treatment chamber, second conveyer belt 33 left surface is located directly over the feed inlet of breaker 34, the discharge gate of breaker 34 is located the top of first conveyer belt 32, the fixed surface is connected with the row who is linked together with the feed inlet of bucket elevator 2 under shell 31 and expects the pipe, first conveyer belt 32 right surface is located directly over arranging the pipe.

Referring to fig. 2, in order to avoid the slag from strongly impacting the first conveyor belt 32 when the slag falls, in the embodiment, the upper surface of the blanking pipe 38 is flush with the upper surface of the outer shell 31, the blanking pipe 38 is located right above the first conveyor belt 32, the upper surface of the blanking pipe 38 is provided with blanking holes, the left surface and the right surface of each blanking hole are fixedly connected with guide plates which are arranged in a staggered manner, and the impact force of the slag when the slag falls is relieved by the guide plates.

Referring to fig. 4, in order to screen slag, the screening assembly 4 in this embodiment includes a screening plate 41, four springs 42 are fixedly connected to a lower surface of the screening plate 41, a mounting seat 43 is fixedly connected to a lower surface of the springs 42, the mounting seat 43 is fixedly connected to an inner peripheral wall of the blanking hole, an electromagnet 44 is fixedly connected to an upper surface of the mounting seat 43, a magnetic block 45 located right above the electromagnet 44 is fixedly connected to a lower surface of the screening plate 41, magnetic poles of the magnetic block 45 and one side of an opposite surface of the electromagnet 44 are the same, and the screening plate 41 is driven to screen slag by repulsive force between the magnetic block 45 and the electromagnet 44 after being energized and self weight after being de-energized.

The working principle of the above embodiment is as follows:

the slag is shoveled into the blanking hopper 35 by a forklift and dumped along the right side of the partition plate 36, so that the slag falls on the upper surface of the screening plate 41, then the electromagnet 44 is turned on and off intermittently, so that the screening plate 41 shakes up and down under the action of the spring 42, slag with smaller particles is directly discharged along the discharging pipe 38, then the slag is conveyed to a slag micro-powder mill 1 by a bucket elevator 2 for slag micro-powder processing, large-particle slag is intercepted on the upper surface of a screening plate 41, an electric control door 37 is driven to turn over by a stepping motor, then the right electromagnet 44 is controlled to be turned on, so that the right side of the screening plate 41 is lifted, the screening plate 41 is inclined to the left, the large-particle slag above the slag crusher can fall to the upper surface of the second conveyor belt 33 through the communicating holes and then is conveyed into the crusher 34 for crushing treatment, and the crushed slag is conveyed to the feeding hole of the bucket elevator 2 through the first conveyor belt 32.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a slay miropowder processing mechanism convenient to slay material loading, includes slay miropowder mill (1) and bucket elevator (2), its characterized in that: a feeding mechanism (3) is arranged on the left surface of the bucket elevator (2);

feed mechanism (3) include shell body (31), fixed mounting has first conveyer belt (32) and second conveyer belt (33) in shell body (31), fixed mounting has breaker (34) that is located between first conveyer belt (32) and second conveyer belt (33) in shell body (31), fixed surface is connected with down hopper (35) on shell body (31), fixed mounting has partition panel (36) in hopper (35) down, partition panel (36) internal rotation is connected with automatically controlled door (37), fixed mounting has unloading pipe (38) that are located second conveyer belt (33) right side in shell body (31), fixed mounting has screening subassembly (4) in unloading pipe (38).

2. The slag micropowder processing mechanism of claim 1, wherein: the feed inlet of slay micronizer (1) is linked together with the discharge gate of bucket elevator (2), set up the treatment chamber in shell body (31), first conveyer belt (32), second conveyer belt (33), breaker (34) and unloading pipe (38) all with treatment chamber front and back two fixed surface be connected.

3. The slag micropowder processing mechanism of claim 1, wherein: first conveyer belt (32) are located second conveyer belt (33) bottom, the direction of rotation of first conveyer belt (32) belt is clockwise rotation, the direction of rotation of second conveyer belt (33) belt is anticlockwise rotation, second conveyer belt (33) left surface is located directly over breaker (34) feed inlet.

4. The slag micropowder processing mechanism of claim 1, wherein: breaker (34) discharge gate is located first conveyer belt (32) top, shell body (31) lower surface fixedly connected with arranges the material pipe that is linked together with bucket elevator (2) feed inlet, first conveyer belt (32) right surface is located and arranges the material directly over the pipe.

5. The slag micropowder processing mechanism of claim 1, wherein: the material loading hole has been seted up to lower hopper (35) upper surface, two fixed surface are connected around partition panel (36) and the material loading hole, the intercommunicating pore has been seted up to partition panel (36) left surface, intercommunicating pore lower surface and partition panel (36) lower surface parallel and level, two surfaces are rotated around automatically controlled door (37) and the intercommunicating pore and are connected.

6. The slag micropowder processing mechanism of claim 1, wherein: partition panel (36) internal fixed mounting has step motor, step motor's output shaft and the pivot fixed connection of automatically controlled door (37), shell body (31) upper surface is seted up and is linked together with the material loading hole and is located the water conservancy diversion hole directly over second conveyer belt (33).

7. The slag micropowder processing mechanism of claim 1, wherein: the feeding device is characterized in that the upper surface of the feeding pipe (38) is flush with the upper surface of the outer shell (31), the feeding pipe (38) is located right above the first conveying belt (32), a feeding hole is formed in the upper surface of the feeding pipe (38), and guide plates which are arranged in a mutually staggered mode are fixedly connected to the left surface and the right surface of the feeding hole.

8. The slag micropowder processing mechanism of claim 1, wherein: screening subassembly (4) are including screening board (41), screening board (41) lower fixed surface is connected with quantity is spring (42) of four, spring (42) lower fixed surface is connected with mount pad (43), mount pad (43) and the downthehole perisporium fixed connection of unloading, fixed surface is connected with electro-magnet (44) on mount pad (43), screening board (41) lower fixed surface is connected with magnetic path (45) that are located electro-magnet (44) directly over.

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