CN111392442B

CN111392442B - A combined graphite slag powder feeding system

Info

Publication number: CN111392442B
Application number: CN202010237376.XA
Authority: CN
Inventors: 聂传凯; 李香祖; 吕红波
Original assignee: Qingdao Lingjun Building Materials Technology Co ltd
Current assignee: Qingdao Lingjun Intelligent Construction New Material Technology Co ltd
Priority date: 2020-03-30
Filing date: 2020-03-30
Publication date: 2021-07-23
Anticipated expiration: 2040-03-30
Also published as: CN111392442A

Abstract

The invention discloses a combined graphite slag micro-powder feeding system, which relates to the field of building material industry and comprises a slide rail, a slide seat, a feeding device, a support frame, a pressing ring, an installation block, a hydraulic telescopic rod, a telescopic pipe, an electric control valve, a feeding hopper, a sealing washer, a rack, a gear shaft, a speed reducer and a motor. According to the design scheme, the stone mill slag is sufficiently vibrated and filtered when entering the feeding device through the design of the combined type vibration spiral diversion feeding device, the caked stone mill slag is shaken and crushed and is effectively filtered, and the two groups of symmetrically installed feeding devices can slide through the sliding seat to perform transposition work, so that the hopper of the feeding device which stops working is thoroughly cleaned, the quality of feeding stone mill slag micro powder is favorably ensured, and meanwhile, the hopper cleaning efficiency is improved.

Description

Combined graphite slag micro powder feeding system

Technical Field

The invention relates to the field of building material industry, in particular to a combined graphite slag micro powder feeding system.

Background

At present, a large amount of stone mill slag is generated in graphite mining, the stone mill slag is widely used as one of environmental protection technologies in application of building materials, but the stone mill slag is generally uneven in raw material mixing caused by the caking problem of the stone mill slag when micro powder grinding is completed for proportioning feeding production of building materials, so that the production quality of the building materials cannot be guaranteed.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides a combined graphite slag micro powder feeding system.

The technical scheme adopted by the invention for solving the technical problems is as follows: a combined graphite slag micro-powder feeding system comprises a slide rail, a slide seat, a feeding device, a support frame, a pressing ring, an installation block, a hydraulic telescopic rod, a telescopic pipe, an electric control valve, a feeding hopper, a sealing washer, a rack, a gear shaft, a speed reducer and a motor, wherein the feeding device comprises a support spring, an installation seat, a discharging barrel support, a discharging barrel, a spiral guide rod, a charging barrel, a vibrator, a hopper, a damping spring, an installation ring, a butt joint pipe, a feeding motor, a feeding speed reducer, a guide rod driving shaft and a vibration filter screen, the slide rail is divided into 2 groups which are symmetrically arranged on the ground of a workshop front part and a rear part, the support frame is arranged on the rear part of the rear end part of the slide rail in a rigid mode, the installation blocks are divided into 2 groups which are symmetrically arranged on the side wall of the pressing ring in a rigid mode, the hydraulic telescopic rods are divided into 2 groups which are symmetrically connected and arranged between the installation block and the lower end face of the top part of the support frame, the telescopic pipe is connected and installed between the upper end face of the compression ring and the lower end face of the feeding hopper, the electric control valve is installed at the lower part of the feeding hopper, the feeding hopper is rigidly installed at the top of the support frame, the sealing washer is installed at the bottom of an annular groove arranged at the bottom face of the compression ring, the rack is rigidly installed at the upper end face of the rear end part of the sliding rail, the gear is meshed with the rack, the gear is rigidly installed at the tail end of a gear shaft, the gear shaft is installed on the sliding seat in a matching way, the head end of the gear shaft is rigidly installed at the power output end of the speed reducer, the speed reducer is fixed on the motor shell through a speed reducer support, the power input end of the speed reducer is rigidly connected with the power output shaft of the motor, the motor is installed at the side face of the rear end of the sliding seat through a motor support, the support spring is connected and installed between the lower end face of the installation seat and the upper end face of the sliding seat, and the discharging barrel is rigidly installed at the upper end face of the installation seat through a discharging barrel support, the spiral guide rod is installed on the inner wall of the discharge barrel in a matching manner, the feed barrel is rigidly installed on the side wall of the upper part of the head end of the discharge barrel, the head end of the discharge barrel is provided with a baffle plate for sealing, the vibrator is installed on the side wall of the feed barrel, the hopper is rigidly and integrally installed on the upper end surface of the feed barrel, the damping spring is connected and installed between the upper end surface of the hopper and the lower end surface of the mounting ring, the mounting ring is rigidly and integrally installed on the outer wall of the butt joint pipe, the butt joint pipe is installed inside the hopper in a matching manner, the upper end of the butt joint pipe is installed in a ring groove arranged on the bottom surface of the compression ring in a matching manner at a butt joint position, the feeding motor is rigidly installed on the head end baffle plate of the discharge barrel through a motor bracket, the feeding speed reducer is fixed on a motor shell through a speed reducer power input end in a rigid connection with a feeding motor power output shaft, and the head end of the guide rod driving shaft is rigidly installed on the power output end of the feeding speed reducer, the tail end of the guide rod driving shaft is connected and installed on a central shaft of the spiral guide rod, and the vibration filter screen is rigidly installed on the inner wall of the upper part of the hopper.

The feeding device is divided into 2 groups and is rigidly mounted on the upper end face of the sliding seat in a bilateral symmetry mode, the telescopic guide posts are mounted inside the supporting springs and the damping springs, 3 groups of the supporting springs which are uniformly distributed in the left and right directions are used as one group, the supporting springs are uniformly distributed and connected between the lower end face of the mounting seat and the upper end face of the sliding seat in the front and back direction, and the damping springs are divided into 4 groups and are uniformly distributed and connected between the upper end face of the hopper and the lower end face of the mounting ring in a 360-degree annular array mode.

The invention has the beneficial effects that the design scheme of the invention ensures that the stone mill slag is fully vibrated and filtered when entering the feeding device through the design of the combined type vibration spiral diversion feeding device, the caked stone mill slag is shaken and crushed and is effectively filtered, and two groups of symmetrically arranged feeding devices can perform transposition work through sliding of the sliding seat, so that the hopper of the feeding device which stops working is thoroughly cleaned, the quality of feeding the stone mill slag micro powder is favorably ensured, and the hopper cleaning efficiency is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a front view of the overall structure of the present invention;

FIG. 2 is a side view of the carriage mounting structure of the present invention;

fig. 3 is a schematic view of the internal structure of the hopper of the present invention.

In the figure, 1 a sliding rail, 2 a sliding seat, 3 a supporting spring, 4 a mounting seat, 5 a discharging barrel support, 6 a discharging barrel, 7 a spiral material guiding rod, 8 a material inlet barrel, 9 a vibrator, 10 a hopper, 11 a damping spring, 12 a mounting ring, 13 a butt joint pipe, 14 a supporting frame, 15 a pressing ring, 16 a mounting block, 17 a hydraulic telescopic rod, 18 a telescopic pipe, 19 an electric control valve, 20 a material inlet hopper, 21 a sealing gasket, 22 a rack, 23 a gear, 24 a gear shaft, 25 a speed reducer, 26 a motor, 27 a feeding motor, 28 a feeding speed reducer, 29 a guide rod driving shaft and 30 a vibration filter screen are arranged.

Detailed Description

In order to more clearly illustrate the technical solution of the present invention, the following further description is made with reference to the accompanying drawings, and it is obvious that the following described drawings are only one embodiment of the present invention, and it is within the scope of the present invention for a person of ordinary skill in the art to obtain other embodiments based on the drawings and the embodiment without any creative effort.

A combined graphite slag micro-powder feeding system comprises a slide rail 1, a slide seat 2, a feeding device, a support frame 14, a pressing ring 15, a mounting block 16, a hydraulic telescopic rod 17, a telescopic pipe 18, an electric control valve 19, a feeding hopper 20, a sealing washer 21, a rack 22, a gear 23, a gear shaft 24, a speed reducer 25 and a motor 26, wherein the feeding device comprises a support spring 3, a mounting seat 4, a discharging barrel support 5, a discharging barrel 6, a spiral material guiding rod 7, a feeding barrel 8, a vibrator 9, a hopper 10, a damping spring 11, a mounting ring 12, a butt joint pipe 13, a feeding motor 27, a feeding speed reducer 28, a guide rod driving shaft 29 and a vibration filter screen 30, the slide rail 1 is symmetrically mounted on the ground of a workshop in front and back in groups, the slide seat 2 is mounted on the slide rail 1 in a matched manner, the support frame 14 is rigidly mounted on the rear part of the rear end part of the slide rail 1, the mounting block 16 is rigidly mounted on the side wall of the pressing ring 15 in groups in a bilaterally symmetrical and integral manner in groups, the hydraulic telescopic rods 17 are symmetrically arranged between the mounting block 16 and the lower end face of the top of the support frame 14 in 2 groups, the telescopic pipe 18 is arranged between the upper end face of the compression ring 15 and the lower end face of the feed hopper 20 in a connecting manner, the electric control valve 19 is arranged at the lower part of the feed hopper 20, the feed hopper 20 is rigidly arranged at the top of the support frame 14, the sealing washer 21 is arranged at the bottom of an annular groove arranged at the bottom face of the compression ring 15, the rack 22 is rigidly arranged at the upper end face of the rear end part of the slide rail 1, the gear 23 is meshed with the rack 22, the gear 23 is rigidly arranged at the tail end of the gear shaft 24, the gear shaft 24 is arranged on the slide carriage 2 in a matching manner, the head end of the gear shaft 24 is rigidly arranged at the power output end of the speed reducer 25, the speed reducer 25 is fixed on the shell of the motor 26 through a speed reducer support, and the power input end of the speed reducer 25 is rigidly connected to the power output shaft of the motor 26, the motor 26 is arranged on the side surface of the rear end of the sliding seat 2 through a motor support, the supporting spring 3 is connected and arranged between the lower end surface of the mounting seat 4 and the upper end surface of the sliding seat 2, the discharging barrel 6 is rigidly arranged on the upper end surface of the mounting seat 4 through a discharging barrel support 5, the spiral guide rod 7 is arranged on the inner wall of the discharging barrel 6 in a matching way, the charging barrel 8 is rigidly arranged on the side wall of the upper end part of the discharging barrel 6, the mounting baffle plate at the head end of the discharging barrel 6 is closed, the vibrator 9 is arranged on the side wall of the charging barrel 8, the hopper 10 is rigidly and integrally arranged on the upper end surface of the charging barrel 8, the damping spring 11 is connected and arranged between the upper end surface of the hopper 10 and the lower end surface of the mounting ring 12, the mounting ring 12 is rigidly and integrally arranged on the outer wall of the butt joint pipe 13, the butt joint pipe 13 is arranged inside the hopper 10 in a matching way, the upper end of the butt joint pipe 13 is arranged on the annular groove arranged on the bottom surface of the pressing ring 15 at the butt joint position in a matching way, the feeding motor 27 is rigidly mounted on a baffle at the head end of the discharging barrel 6 through a motor support, the feeding speed reducer 28 is fixed on a shell of the feeding motor 27 through a speed reducer support, the power input end of the feeding speed reducer 28 is rigidly connected to the power output shaft of the feeding motor 27, the head end of the guide rod driving shaft 29 is rigidly mounted on the power output end of the feeding speed reducer 28, the tail end of the guide rod driving shaft 29 is connected to the central shaft of the spiral guide rod 7, and the vibration filter screen 30 is rigidly mounted on the inner wall of the upper part of the hopper 10.

In detail, the feeding device is rigidly mounted on the upper end surface of the sliding seat 2 in a bilateral symmetry mode in groups, the telescopic guide posts are mounted inside the supporting springs 3 and the damping springs 11, the supporting springs 3 are uniformly distributed and mounted between the lower end surface of the mounting seat 4 and the upper end surface of the sliding seat 2 in a front-back direction by taking 3 groups which are uniformly distributed in the left-right direction as a group, and the damping springs 11 are uniformly distributed and mounted between the upper end surface of the hopper 10 and the lower end surface of the mounting ring 12 in groups of 360-degree annular arrays in 4 groups.

The above embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and the scope of the present invention is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present invention, and such modifications and equivalents should also be considered as falling within the scope of the present invention.

Claims

1. A combined graphite slag micropowder feeding system, comprising a sliding rail (1), a sliding seat (2), a feeding device, a support frame (14), a pressing ring (15), a mounting block (16), a hydraulic pressure Telescopic rod (17), telescopic tube (18), electric control valve (19), feeding hopper (20), sealing gasket (21), rack (22), gear (23), gear shaft (24), reducer (25), a motor (26), characterized in that: the feeding device comprises a support spring (3), a mounting seat (4), a discharge cylinder bracket (5), a discharge cylinder (6), and a spiral guide rod (7), feeding barrel (8), vibrator (9), hopper (10), shock-absorbing spring (11), mounting ring (12), butt pipe (13), feeding motor (27), feeding The reducer (28), the guide rod drive shaft (29), the vibration filter (30), the sliding rails (1) are installed in two groups symmetrically on the workshop floor, and the sliding seat (2) is installed on the sliding Rail (1), the support frame (14) is rigidly mounted on the rear part of the rear end of the slide rail (1), and the mounting block (16) is divided into two groups of left-right symmetrical rigid one-piece mounted on the pressing ring (15) On the side wall, the hydraulic telescopic rods (17) are symmetrically connected and installed in two groups between the mounting block (16) and the lower end surface of the top of the support frame (14), and the telescopic tubes (18) are connected and installed on the compression ring (15). ) between the upper end face of the hopper (20) and the lower end face of the feeding hopper (20), the electric control valve (19) is installed at the lower part of the feeding hopper (20), the feeding hopper (20) is rigidly installed on the top of the support frame (14), and the The sealing washer (21) is mounted on the bottom of the annular groove provided on the bottom surface of the pressing ring (15), the rack (22) is rigidly mounted on the upper end face of the rear end portion of the slide rail (1), and the gear (23) is connected to the rack. (22) meshing, the gear (23) is rigidly mounted on the end of the gear shaft (24), the gear shaft (24) is fitted on the sliding seat (2), and the first end of the gear shaft (24) is rigidly mounted on the speed reducer The power output end of the speed reducer (25), the speed reducer (25) is fixed to the housing of the motor (26) through the speed reducer bracket, and the power input end of the speed reducer (25) is rigidly connected to the power output shaft of the motor (26), so The motor (26) is installed on the rear end side of the sliding seat (2) through a motor bracket, and the supporting spring (3) is connected and installed between the lower end surface of the mounting seat (4) and the upper end surface of the sliding seat (2). The material barrel (6) is rigidly mounted on the upper end surface of the mounting seat (4) through the material discharge barrel bracket (5), the screw guide rod (7) is fitted on the inner wall of the material discharge barrel (6), and the feeding barrel ( 8) Rigidly installed on the upper side wall of the head end of the discharge cylinder (6), the head end of the discharge cylinder (6) is installed with a baffle to close, and the vibrator (9) is installed on the side wall of the feed cylinder (8), The hopper (10) is rigidly and integrally installed on the upper end face of the feeding cylinder (8), and the damping spring (11) is connected and installed between the upper end face of the hopper (10) and the lower end face of the mounting ring (12). The mounting ring (12) is rigidly and integrally mounted on the outer wall of the butt pipe (13), and the butt pipe (13) is fitted with Inside the hopper (10), the upper end of the butt pipe (13) is fitted to the annular groove provided on the bottom surface of the pressing ring (15) at the docking position, and the feeding motor (27) is rigidly mounted on the discharge barrel through the motor bracket (6) Head end baffle, the feeding reducer (28) is fixed to the housing of the feeding motor (27) through the reducer bracket, and the power input end of the feeding reducer (28) is rigidly connected to the feeding motor (27) Power output shaft, the head end of the guide rod drive shaft (29) is rigidly installed on the power output end of the feed reducer (28), and the end of the guide rod drive shaft (29) is connected and installed on the screw guide The central axis of the rod (7), the vibrating filter screen (30) is rigidly mounted on the upper inner wall of the hopper (10).

2. A combined graphite slag micropowder feeding system according to claim 1, characterized in that, the feeding device is divided into 2 groups and is rigidly mounted on the upper end surface of the sliding seat (2) symmetrically, and the supporting spring (2). 3) A telescopic guide column is installed inside the shock-absorbing spring (11), and the support spring (3) is connected to the lower end surface of the mounting seat (4) and the sliding Between the upper end faces of the seat (2), the shock-absorbing springs (11) are divided into 4 groups of 360° annular arrays, and are evenly connected and installed between the upper end face of the hopper (10) and the lower end face of the mounting ring (12).