CN109012838B

CN109012838B - A smash system for in graphite section of thick bamboo production process

Info

Publication number: CN109012838B
Application number: CN201810715846.1A
Authority: CN
Inventors: 陈良洪
Original assignee: Hubei Hongye Building Materials Technology Development Co ltd
Current assignee: Hubei Hongye Building Materials Technology Development Co ltd
Priority date: 2018-06-29
Filing date: 2018-06-29
Publication date: 2020-05-05
Anticipated expiration: 2038-06-29
Also published as: CN109012838A

Abstract

The invention discloses a crushing system used in the production process of a graphite barrel, which comprises a first conveying belt device used for conveying graphite ore, wherein a crushing box is arranged below the conveying tail end of the first conveying belt device, a roller type crushing device is arranged in the crushing box, a screen is horizontally arranged below a discharge port of the roller type crushing device, one end of the screen extends into a guide disc, the other end of the screen is hinged with the output end of a transverse reciprocating mechanism, a top disc is arranged below the screen, and a second conveying belt device is arranged below the discharge end of the crushing box; according to the invention, the graphite ore is rapidly crushed by the roller type crushing device, the graphite ore is rapidly screened by the transverse reciprocating mechanism, and meanwhile, the processes of automatically cleaning the screen and recovering the un-crushed and completely-crushed graphite particles are realized by the cooperation of the screen, the guide disc, the top disc, the second conveying belt device, the first electric telescopic rod and the second electric telescopic rod, so that the labor intensity of manually cleaning the screen is reduced, and the graphite resource is effectively saved.

Description

A smash system for in graphite section of thick bamboo production process

Technical Field

The invention relates to the technical field of graphite cylinder production, in particular to a crushing system used in the production process of a graphite cylinder.

Background

Graphite barrel is in the production process, need smash graphite ore, and present graphite ore smashes system just directly sends into next process after smashing graphite ore, owing to smash effect and degree of consistency differ, so can appear smashing the degree and can not reach the graphite ore powder of requirement and enter into next process, influenced graphite barrel's production quality.

Disclosure of Invention

The invention aims to overcome the defects and provide a crushing system for the production process of a graphite cylinder, which can simultaneously crush and screen graphite ores.

In order to solve the technical problems, the invention adopts the technical scheme that: a crushing system used in the production process of a graphite barrel comprises a first conveying belt device used for conveying graphite ores, a crushing box is arranged below the conveying end of the first conveying belt device, a roller type crushing device is arranged in the crushing box, a screen is horizontally arranged below a discharge port of the roller type crushing device, one end of the screen extends into a guide disc, the other end of the screen is hinged with the output end of a transverse reciprocating movement mechanism, a top disc is arranged below the screen, and a second conveying belt device is arranged below the discharge end of the crushing box.

Preferably, the roller type crushing device comprises a first crushing roller and a second crushing roller which are horizontally arranged, the first crushing roller is connected with a driving wheel through a first rotating shaft, the second crushing roller is connected with a driven wheel through a second rotating shaft, the driving wheel is connected with the driven wheel through a belt, and the driving wheel is connected with a motor through a speed reducer.

Preferably, horizontal reciprocating motion mechanism is including the carriage release lever that is L type structure, carriage release lever one end is connected with the screen cloth avris is articulated, and the other end is connected with oval shape frame bottom, both ends all are equipped with the straight-tooth about the oval shape frame, be equipped with incomplete gear in the oval shape frame, the tooth and the straight-tooth meshing of incomplete gear, slide bar and the gyro wheel sliding connection at support frame top are passed through to oval shape frame both sides, incomplete gear input is connected with the rotating electrical machines output through the axis of rotation.

Preferably, the support frame and the side wall of the crushing box are provided with linear sliding bearings in sliding fit with the moving rod.

Preferably, the guiding disc side is connected with the crushing box side wall through a first electric telescopic rod arranged horizontally, and the top disc bottom is connected with a second electric telescopic rod arranged vertically.

Preferably, one end of the screen is also provided with a guide rod, and the guide rod extends into the guide disc.

Preferably, a vibration motor is further arranged at the bottom of the screen.

Preferably, a recovery hopper is further arranged on one side of the second conveyor belt device.

Preferably, a spring is further arranged on one side of the top of the recovery hopper.

Preferably, the crushing box is also provided with a receiving hopper.

The invention has the beneficial effects that: according to the invention, the roller type crushing device is used for realizing the rapid crushing process of the graphite ore, the transverse reciprocating mechanism is used for realizing the rapid screening process of the graphite ore, and meanwhile, the screen, the guide disc, the top disc, the second conveyor belt device, the first electric telescopic rod and the second electric telescopic rod are cooperatively matched, so that the processes of automatically cleaning the screen and recovering the un-crushed complete graphite particles can be realized, the labor intensity of manually cleaning the screen is reduced, and the graphite resource is effectively saved.

Drawings

FIG. 1 is a schematic diagram of a pulverizing system used in a graphite barrel production process;

FIG. 2 is a schematic view of the roller mill of FIG. 1;

FIG. 3 is a schematic structural view of the traverse mechanism in FIG. 1;

FIG. 4 is a schematic view showing a connection structure between a partial gear, a rotary shaft and a rotary motor;

in the figure, a first conveyor belt device 1, a crushing box 2, a receiving hopper 2.1, a roller type crushing device 3, a first crushing roller 3.1, a second crushing roller 3.2, a first rotating shaft 3.3, a driving wheel 3.4, a second rotating shaft 3.5, a driven wheel 3.6, a belt 3.7, a speed reducer 3.8, a motor 3.9, a screen 4, a guide rod 4.1, a vibration motor 4.2, a guide disc 5, a transverse reciprocating mechanism 6, a moving rod 6.1, an oval frame 6.2, a straight tooth 6.3, an incomplete gear 6.4, a sliding rod 6.5, a support frame 6.6, a roller 6.7, a rotating shaft 6.8, a rotating motor 6.9, a linear sliding bearing 6.10, a top disc 7, a second conveyor belt device 8, a first electric telescopic rod 9, a second electric telescopic rod 10, a recovery hopper 11 and a spring 12.

Detailed Description

The invention is described in further detail below with reference to the figures and specific embodiments.

As shown in fig. 1 to 4, a crushing system used in a graphite barrel production process comprises a first conveyor belt device 1 used for conveying graphite ore, a crushing box 2 is arranged below the conveying end of the first conveyor belt device 1, a roller type crushing device 3 is arranged in the crushing box 2, a screen 4 is horizontally arranged below a discharge port of the roller type crushing device 3, one end of the screen 4 extends into a guide disc 5, the other end of the screen is hinged with the output end of a transverse reciprocating mechanism 6, a top disc 7 is arranged below the screen 4, and a second conveyor belt device 8 is arranged below the discharge end of the crushing box 2.

Preferably, the roller mill 3 includes a first mill roller 3.1 and a second mill roller 3.2 which are horizontally arranged, the first mill roller 3.1 is connected with a driving wheel 3.4 through a first rotating shaft 3.3, the second mill roller 3.2 is connected with a driven wheel 3.6 through a second rotating shaft 3.5, the driving wheel 3.4 is connected with the driven wheel 3.6 through a belt 3.7, and the driving wheel 3.4 is connected with a motor 3.9 through a speed reducer 3.8.

Preferably, horizontal reciprocating motion mechanism 6 is including the carriage release lever 6.1 that is L type structure, carriage release lever 6.1 one end is connected with 4 avris hinges of screen cloth, and the other end is connected with oval shape frame 6.2 bottom, both ends all are equipped with straight-tooth 6.3 about the oval shape frame 6.2, be equipped with incomplete gear 6.4 in the oval shape frame 6.2, the tooth and the straight-tooth 6.3 meshing of incomplete gear 6.4, slide bar 6.5 and the gyro wheel 6.7 sliding connection at support frame 6.6 top are passed through to oval shape frame 6.2 both sides, incomplete gear 6.4 input is passed through axis of rotation 6.8 and is connected with rotating electrical machines 6.9 output. After the design, the rotating motor 6.9 drives the rotating shaft 6.8 to rotate after working, so that the incomplete gear 6.4 continuously rotates, when the toothed part of the incomplete gear 6.4 rotates to the upper end of the oval frame 6.2, the toothed part is meshed with the straight teeth 6.3 at the upper end, so as to drive the oval frame 6.2 to horizontally move towards one side, and when the toothed part rotates to the lower end of the oval frame 6.2, the toothed part is meshed with the straight teeth 6.3 at the lower end, so as to drive the oval frame 6.2 to horizontally move towards the other opposite direction; the waist circular frame 6.2 bottom is through carriage bar 6.1 and screen cloth 4 fixed connection to realize screen cloth 4's horizontal reciprocating motion process, thereby can carry out the screening process to graphite ore powder fast. In addition, preferably, the support frame 6.6 is vertically arranged and is fixed to the side wall of the crushing box 2 by a horizontally arranged support plate.

Preferably, the support frame 6.6 and the side wall of the crushing box 2 are provided with linear sliding bearings 6.10 which are in sliding fit with the moving rod 6.1. The linear sliding bearing 6.10 can effectively reduce the friction force generated by the moving rod 6.1 when moving horizontally with the support frame 6.6 and the crushing box 2, so that the whole process is more stable.

Preferably, the side of the guide disc 5 is connected with the side wall of the crushing box 2 through a first electric telescopic rod 9 arranged horizontally, and the bottom of the top disc 7 is connected with a second electric telescopic rod 10 arranged vertically.

Preferably, one end of the screen 4 is further provided with a guide rod 4.1, and the guide rod 4.1 extends into the guide disc 5. When the graphite ore on the screen cloth 4 needs to be poured off, first electric telescopic handle 9 contracts, make the guide disc 5 break away from guide bar 4.1 of screen cloth 4, screen cloth 4 takes place the slope downwardly rotating, make the complete graphite granule landing of not smashing on the screen cloth 4, thereby be convenient for collect not smashing complete graphite granule, and do benefit to screen cloth 4 clean up, then second electric telescopic handle 10 extension, drive the overhead pan 7 and move up, after the overhead pan 7 contacts screen cloth 4 lower surface, make screen cloth 4 upwards rotatory, behind the hole parallel and level that guide bar 4.1 and guide disc 5 of screen cloth 4 correspond, first electric telescopic handle 9 extension drives guide disc 5 translation, thereby overlap on guide bar 4.1 again, begin the crushing and the screening process of a new round.

Preferably, the bottom of the screen 4 is also provided with a vibrating motor 4.2. The vibration motor 4.2 can accelerate the speed of the graphite particles which are not completely crushed to slide down from the screen 4.

Preferably, a recovery bucket 11 is further arranged on one side of the second conveyor belt device 8. The recovery hopper 11 facilitates the collection of graphite particles that have not been completely crushed and can then be transported to the crushing box 2 for re-crushing.

Preferably, a spring 12 is further arranged on one side of the top of the recovery bucket 11. The design of the spring 12 can facilitate the vibration of the vibrating motor 4.2 and the vibration of the screen 4 in a larger range after contacting the spring 12, thereby greatly accelerating the speed of the graphite particles which are not completely crushed to slide down from the screen 4.

Preferably, the crushing box 2 is further provided with a receiving hopper 2.1. Preferably, the receiving hopper 2.1 is also provided with a valve in this embodiment, so that the feeding process of the crushing box 2 can be controlled.

The working principle of the embodiment is as follows:

firstly, graphite ore to be crushed is conveyed into a receiving hopper 2.1 through a first conveying belt device 1, then the graphite ore is discharged into a crushing box 2, the crushed graphite falls onto a screen 4 through the rotating extrusion of a first crushing roller 3.1 and a second crushing roller 3.2 in a roller type crushing device 3, a moving rod 6.1 drives the screen 4 to horizontally reciprocate by starting a rotating motor 6.9 of a transverse reciprocating mechanism 6, wherein the guide rod 4.1 stably slides in a guide disc 5, and a good limiting and guiding effect is achieved on the horizontal movement of the screen 4; the screen 4 moves horizontally and reciprocally to rapidly carry out the screening process of the graphite ore powder, the fine graphite powder falls onto the second conveying belt device 8 from the screen holes of the screen 4 and then is conveyed to the next procedure, and the coarse graphite which is not completely crushed is retained on the screen 4; after a batch of graphite ores are crushed, the first electric telescopic rod 9 is contracted, so that the guide disc 5 is separated from the guide rod 4.1 of the screen 4, the screen 4 rotates obliquely downwards and then contacts the spring 12, the vibrating motor 4.2 is started, the screen can generate vibration with a larger amplitude, graphite particles which are not completely crushed on the screen 4 slide down to the recovery hopper 11, and the recovery hopper 11 can convey the graphite particles which are not completely crushed into the crushing box 2 to be crushed again after collecting the graphite particles which are not completely crushed, so that waste is avoided, and resources are saved; then with screen cloth 4 clean up back, second electric telescopic handle 10 extension drives a set 7 and moves up, after 7 contact screen cloth 4 lower surfaces of top dish for screen cloth 4 upwards rotates, and after the hole parallel and level that guide bar 4.1 and guide disc 5 of screen cloth 4 correspond, first electric telescopic handle 9 extension drives 5 translations of guide disc, thereby overlaps on guide bar 4.1 again, can begin the crushing and the screening process of new round.

The above-described embodiments are merely preferred embodiments of the present invention, and should not be construed as limiting the present invention, and features in the embodiments and examples in the present application may be arbitrarily combined with each other without conflict. The protection scope of the present invention is defined by the claims, and includes equivalents of technical features of the claims. I.e., equivalent alterations and modifications within the scope hereof, are also intended to be within the scope of the invention.

Claims

1. A crushing system for a graphite cylinder production process comprises a first conveying belt device (1) for conveying graphite ore, and is characterized in that: a crushing box (2) is arranged below the conveying end of the first conveying belt device (1), a roller type crushing device (3) is arranged in the crushing box (2), a screen (4) is horizontally arranged below the discharging port of the roller type crushing device (3), one end of the screen (4) extends into a guide disc (5), the other end of the screen is hinged with the output end of a transverse reciprocating mechanism (6), a top disc (7) is arranged below the screen (4), and a second conveying belt device (8) is arranged below the discharging end of the crushing box (2);

the side part of the guide disc (5) is connected with the side wall of the crushing box (2) through a first electric telescopic rod (9) horizontally arranged, and the bottom of the top disc (7) is connected with a second electric telescopic rod (10) vertically arranged.

2. A comminution system for use in a graphite barrel production process in accordance with claim 1, in which: roller type reducing mechanism (3) smash roller (3) including first crushing roller (3.1) and second crushing roller (3.2) that the level set up, first crushing roller (3.1) are connected with action wheel (3.4) through first rotation axis (3.3), second crushing roller (3.2) are connected with follow driving wheel (3.6) through second rotation axis (3.5), action wheel (3.4) are connected through belt (3.7) with follow driving wheel (3.6), action wheel (3.4) are connected with motor (3.9) through speed reducer (3.8).

3. A comminution system for use in a graphite barrel production process in accordance with claim 1 or 2, in which: horizontal reciprocating motion mechanism (6) is including carriage release lever (6.1) that is L type structure, carriage release lever (6.1) one end is connected with screen cloth (4) avris are articulated, and the other end is connected with oval frame (6.2) bottom, both ends all are equipped with straight-tooth (6.3) about oval frame (6.2), be equipped with incomplete gear (6.4) in oval frame (6.2), the tooth and the straight-tooth (6.3) meshing of incomplete gear (6.4), gyro wheel (6.7) sliding connection at slide bar (6.5) and support frame (6.6) top is passed through to oval frame (6.2) both sides, incomplete gear (6.4) input is passed through axis of rotation (6.8) and is connected with rotating electrical machines (6.9) output.

4. A comminution system for use in a graphite barrel production process as claimed in claim 3 in which: the side walls of the support frame (6.6) and the crushing box (2) are provided with linear sliding bearings (6.10) which are in sliding fit with the moving rod (6.1).

5. A comminution system for use in a graphite barrel production process in accordance with claim 1, in which: and one end of the screen (4) is also provided with a guide rod (4.1), and the guide rod (4.1) extends into the guide disc (5).

6. A comminution system for use in a graphite barrel production process in accordance with claim 1, in which: and a vibrating motor (4.2) is also arranged at the bottom of the screen (4).

7. A comminution system for use in a graphite barrel production process in accordance with claim 1, in which: and a recovery hopper (11) is also arranged on one side of the second conveyor belt device (8).

8. A comminution system for use in a graphite barrel production process in accordance with claim 7, in which: and a spring (12) is also arranged on one side of the top of the recovery hopper (11).

9. A comminution system for use in a graphite barrel production process in accordance with claim 1, in which: the crushing box (2) is also provided with a receiving hopper (2.1).