CN212732422U - Accurate feeding mechanism of graphite processing - Google Patents

Abstract

The utility model relates to a graphite processing technology field especially relates to an accurate feed mechanism of graphite processing, including organism, connecting pipe and footstock, from upwards through welded fastening between organism, connecting pipe and the footstock, and the interior roof department of organism installs the filter screen, rotates between the inner wall of footstock and is provided with the guide shaft, and the top of guide shaft is connected with driving motor to install the pivot in the middle of the diapire of guide shaft, the cover has the multiunit to smash the cutter in the pivot, weld the diaphragm between the inner wall of connecting pipe, the bottom of pivot is inserted in the diaphragm and is connected with it rotation, slides through the baffle between the both sides outer wall of diaphragm below and is provided with the drive seat. Compared with the prior art, the utility model discloses volume when having reduced graphite effectively and having dropped into the organism has avoided the graphite to block up or the card shell condition in equipment.

Description

Accurate feeding mechanism of graphite processing

Technical Field

The utility model relates to a graphite processing technology field especially relates to an accurate feed mechanism of graphite processing.

Background

Graphite is an allotrope of carbon, is a gray black opaque solid, has stable chemical properties, is corrosion resistant, and is not easy to react with acid, alkali and other medicaments. It can be used as antiwear agent and lubricant, high-purity graphite as neutron moderator in atomic reactor, crucible, electrode, brush, dry cell, graphite fibre, heat exchanger, cooler, arc furnace, arc lamp and pencil lead.

When processing graphite, some graphite has a large volume, and is easy to cause blockage or jamming after being thrown into equipment, so a device is needed to solve the problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems in the prior art and providing an accurate feeding mechanism for graphite processing.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a graphite processing accurate feeding mechanism comprises a machine body, a connecting pipe and a top seat, wherein the machine body, the connecting pipe and the top seat are fixed by welding from bottom to top;

the inner wall of connecting pipe has welded the diaphragm between, the bottom of pivot is inserted in the diaphragm and is rotated with it and be connected, slides through the baffle below between the both sides outer wall of diaphragm and is provided with the drive seat, and one side of drive seat is connected with linear electric motor, and installs the grinding wheel through two sets of extension boards in the middle of the diapire of drive seat, and the internally mounted of one of them extension board has the rotating electrical machines who is connected with the grinding wheel.

Preferably, a guide groove is formed between the inner walls of the top seat, the guide groove is of an annular structure, and two ends of the guide shaft are rotatably arranged in the guide groove.

Preferably, a top plate is welded between the inner walls of the top seat, and the driving motor is installed on the top plate.

Preferably, the top wall of the transverse plate is embedded with a bearing in the middle of the surface thereof, and the bottom end of the rotating shaft is inserted into the bearing.

Preferably, guide holes are formed in the outer walls of the two sides of the transverse plate, the guide plates are welded between the side walls of the driving seat, and the guide plates are arranged in the guide holes in a sliding mode.

Preferably, the bottom wall of the driving seat and the support plate are fixed by welding.

The utility model has the advantages that:

through the inside at the inlet pipe set up crushing cutter, adorn it in the pivot to rotate through driving motor, then make the graphite after smashing pulverize by the runner wheel once more, thereby make the graphite after pulverizing fall into in the organism, compare in prior art, the utility model discloses volume when having reduced graphite effectively and having dropped into the organism has avoided graphite to block up or the card shell condition in equipment.

Drawings

Fig. 1 is a schematic structural view of an accurate feeding mechanism for graphite processing according to the present invention;

fig. 2 is a schematic top view of a top seat of the precise feeding mechanism for graphite processing according to the present invention;

fig. 3 is the utility model provides a drive seat and grinding wheel installation schematic diagram of the accurate feed mechanism of graphite processing.

In the figure: 1 machine body, 11 filter screens, 2 feeding pipes, 21 transverse plates, 211 guide holes, 3 top seats, 31 guide shafts, 32 rotating shafts, 33 guide grooves, 34 top plates, 4 driving seats, 41 support plates, 42 guide plates and 5 grinding wheels.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, an accurate feeding mechanism for graphite processing comprises a machine body 1, a connecting pipe 2 and a top seat 3, wherein the machine body 1, the connecting pipe 2 and the top seat 3 are fixed by welding from bottom to top, a filter screen 11 is mounted on the inner top wall of the machine body 1 through screws, the filter screen 11 is used for screening graphite to prevent overlarge graphite from falling into the machine body 1, guide shafts 31 are rotatably arranged between the inner walls of the top seat 3, guide grooves 33 are formed between the inner walls of the top seat 3 and used for limiting and guiding the guide shafts 31, the guide grooves 33 are of an annular structure, two ends of each guide shaft 31 are rotatably arranged in the corresponding guide groove 33, a driving motor is connected above each guide shaft 31, a top plate 34 is welded between the inner walls of the top seat 3, the driving motor is mounted on the top plate 34, a rotating shaft 32 is mounted in the middle of the bottom wall of each guide shaft 31, and the rotating shaft 32, a plurality of groups of crushing cutters (the volume of the cutters is gradually increased from top to bottom) are sleeved on the rotating shaft 32;

furthermore, a transverse plate 21 is welded between the inner walls of the connecting pipes 2, the transverse plate 21 is used for auxiliary fixing of the rotating shaft 32 and fixedly mounting of the driving seat 4, a bearing is embedded in the middle of the surface of the top wall of the transverse plate 21, the bottom end of the rotating shaft 32 is inserted into the bearing, the driving seat 4 is arranged below the outer walls of the two sides of the transverse plate 21 in a sliding manner through a guide plate 42, the driving seat 4 is used for driving the grinding wheel 5 to roll, guide holes 211 are formed in the outer walls of the two sides of the transverse plate 21, a guide plate 42 is welded between the side walls of the driving seat 4 and used for guiding the driving seat 4, the guide plate 42 is arranged in the guide hole 211 in a sliding manner, one side of the driving seat 4 is connected with a linear motor, the output shaft of the linear motor is fixedly connected with the guide plate 42, the linear motor is installed on the outer wall of the feeding pipe 2, support, the grinding wheel 5 is used for grinding graphite, and a rotating motor connected with the grinding wheel 5 is arranged inside one support plate 41.

In this embodiment, when the power is turned on and the device is started, the driving motor drives the guide shaft 31 to rotate in the guide slot 33, and the rotating shaft 32 and the crushing cutter thereon are synchronously driven to rotate along with the rotation of the guide shaft 31, in addition, the linear motor drives the guide plate 42 to slide along the guide hole 211, so that the guide plate 42 synchronously drives the driving seat 4 to slide, and meanwhile, the rotating motor drives the wheel shaft to rotate, and the grinding wheel 5 rotates along with the rotation and moves back and forth along with the driving seat 4;

drop into graphite in the footstock 3, the graphite piece falls along inlet pipe 2, is garrulous when smashing the cutter through, then falls on filter screen 11, and the graphite of tiny particle directly falls from filter screen 11, gets into in the organism 1, and the graphite that the volume is still great, then constantly garrulous under the round trip roll of grinding wheel 5, falls again when falling from filter screen 11 to can following, and the back is ended, and closing equipment to it can to cut off the power.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. The accurate feeding mechanism for graphite processing comprises a machine body (1), a connecting pipe (2) and a top seat (3), and is characterized in that the machine body (1), the connecting pipe (2) and the top seat (3) are fixed by welding from bottom to top, a filter screen (11) is installed at the inner top wall of the machine body (1), a guide shaft (31) is rotatably arranged between the inner walls of the top seat (3), a driving motor is connected above the guide shaft (31), a rotating shaft (32) is installed in the middle of the bottom wall of the guide shaft (31), and a plurality of groups of crushing cutters are sleeved on the rotating shaft (32);

transverse plates (21) are welded between the inner walls of the connecting pipes (2), the bottom ends of the rotating shafts (32) are inserted into the transverse plates (21) and are connected with the transverse plates in a rotating mode, driving seats (4) are arranged between the outer walls of the two sides of the transverse plates (21) in a sliding mode below the outer walls of the two sides of the transverse plates through guide plates (42), one sides of the driving seats (4) are connected with linear motors, grinding wheels (5) are installed in the middle of the bottom walls of the driving seats (4) through two groups of support plates (41), and rotating motors connected with the grinding wheels (5) are installed inside one of the support plates (41.

2. The graphite machining precision feeding mechanism of claim 1, wherein a guide groove (33) is formed between the inner walls of the top seat (3), the guide groove (33) is of an annular structure, and two ends of the guide shaft (31) are rotatably arranged in the guide groove (33).

3. The graphite processing accurate feeding mechanism according to claim 1, characterized in that a top plate (34) is welded between the inner walls of the top seat (3), and a driving motor is installed on the top plate (34).

4. The graphite processing accurate feeding mechanism as claimed in claim 1, wherein the top wall of the transverse plate (21) is embedded with a bearing in the middle of the surface thereof, and the bottom end of the rotating shaft (32) is inserted into the bearing.

5. The graphite processing accurate feeding mechanism according to claim 1, wherein guide holes (211) are formed in the outer walls of the two sides of the transverse plate (21), the guide plate (42) is welded between the side walls of the driving seat (4), and the guide plate (42) is slidably arranged in the guide holes (211).

6. The graphite machining precision feeding mechanism is characterized in that the bottom wall of the driving seat (4) and the support plate (41) are fixed through welding.

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