CN115634757B - Intelligent environment-friendly production furnace for graphite production - Google Patents

Abstract

The invention discloses an intelligent environment-friendly production furnace for graphite production, which comprises a graphite production furnace body, a rotary type cutting pre-crushing mechanism, a reciprocating type efficiency improving pre-crushing mechanism, a stable type buffering positioning mechanism and a rebound type vibration anti-blocking mechanism, wherein the rotary type cutting pre-crushing mechanism is arranged on the graphite production furnace body and comprises a motion pre-crushing bin, a mounting shaft is arranged in the motion pre-crushing bin, a plurality of groups of pre-crushing cutter groups are connected on the mounting shaft, and the reciprocating type efficiency improving pre-crushing mechanism is arranged on one side of the motion pre-crushing bin and is used for driving the motion pre-crushing bin to shake. According to the invention, through the arrangement of the corresponding mechanism on the graphite production furnace, the graphite can be pre-crushed, the size can be more uniform, the heating speed is improved when the graphite is processed, the experimental efficiency of the graphite production furnace is improved, and meanwhile, the consumption of heat energy is reduced, so that the waste is reduced, and the environment is protected.

Description

Intelligent environment-friendly production furnace for graphite production

Technical Field

The invention belongs to the technical field of graphite production, and particularly relates to an intelligent environment-friendly production furnace for graphite production.

Background

Graphite is an allotrope of carbon, is a gray black and opaque solid, has stable chemical property, is corrosion-resistant, is not easy to react with agents such as acid, alkali and the like, can be used as an antiwear agent and a lubricant, can be used as a neutron moderator in an atomic reactor, can also be used for manufacturing a crucible, an electrode, a brush, a dry cell, graphite fiber, a heat exchanger, a cooler, an arc furnace, an arc lamp, a pencil lead and the like, and the continuous graphitization furnace is a processing furnace for producing graphitized products in a continuous output mode.

In the process of processing graphite by a graphite production furnace, a pre-crushing mechanism is not generally arranged, the size of the graphite cannot be unified, and part of larger graphite is heated slowly when being processed, so that a large amount of time is wasted, the use efficiency of the graphite production furnace is reduced, and meanwhile, heat energy is consumed in a large amount, so that the waste is caused, and the environment is not protected enough.

Therefore, in order to solve the above technical problems, it is necessary to provide an intelligent environment-friendly production furnace for graphite production.

Disclosure of Invention

The invention aims to provide an intelligent environment-friendly production furnace for graphite production, which solves the problems that the treatment and heating processes of the part of larger graphite are slower, time is wasted, heat energy is wasted and the environment is not protected enough.

In order to achieve the above object, an embodiment of the present invention provides the following technical solution:

an intelligent environmental protection type production furnace for graphite production, comprising: the device comprises a graphite production furnace body, a rotary cutting pre-crushing mechanism, a reciprocating type efficiency-improving pre-crushing mechanism, a stable buffer positioning mechanism and a rebound type vibration anti-blocking mechanism;

the graphite production furnace comprises a graphite production furnace body, wherein a rotary type cutting pre-crushing mechanism is arranged on the graphite production furnace body and comprises a moving pre-crushing bin, a mounting shaft is arranged in the moving pre-crushing bin, and a plurality of groups of pre-crushing cutter groups are connected to the mounting shaft;

one side of the motion pre-crushing bin is provided with a reciprocating type effect-improving pre-crushing mechanism for driving the motion pre-crushing bin to shake;

the graphite production furnace body is connected with a stable type buffering and positioning mechanism for stabilizing the lifting movement pre-crushing bin;

the graphite production furnace body is connected with a rebound type vibration anti-blocking mechanism for reducing the blocking of graphite.

Further, the moving pre-crushing bin is connected with a first motor, and the first motor can drive the installation shaft to rotate, so that the pre-crushing cutter group can be driven to rotate in the moving pre-crushing bin, and the pre-crushing cutter group can pre-crush graphite;

the first motor penetrates through the motion pre-crushing bin and the mounting shaft, so that the first motor is convenient to drive the mounting shaft, and corresponding power is provided for rotation of the mounting shaft;

the utility model discloses a graphite cutting machine, including the cutting knife group that smashes in advance, be connected with a plurality of fixed cutting bars on the cutting knife group that smashes in advance, not only can fix the cutting knife group that smashes in advance, reduced the possibility that the cutting knife group that smashes in advance scattered, can also assist the cutting knife group that smashes in advance to graphite, promoted the efficiency that graphite was smashed in advance, fixed cutting bar runs through the cutting knife group that smashes in advance and sets up.

Further, the feeding bin is connected to the moving pre-crushing bin, and graphite can be fed from the position of the feeding bin, so that the moving pre-crushing bin can be supplemented with graphite at any time, and the feeding bin penetrates through the moving pre-crushing bin;

the anti-blocking blanking net is connected to one side of the motion pre-crushing bin, which is far away from the feeding bin, so that the crushed graphite is conveniently discharged, and the graphite can enter the graphite production furnace body;

the blanking groove matched with the anti-blocking blanking net is cut on the motion pre-crushing bin, so that the anti-blocking blanking net is conveniently fixed, the stability of the anti-blocking blanking net is improved, and the possibility that the anti-blocking blanking net falls is reduced.

Further, the reciprocating type efficiency-improving pre-crushing mechanism comprises a positioning mounting plate, so that the second motor is convenient to fix, and corresponding assistance is provided for the stability of the second motor;

the positioning mounting plate is connected with a second motor, and can drive the rotation of the driving rotary disk, so that corresponding power is provided for the rotation of the driving rotary disk;

the second motor runs through the positioning mounting plate and is arranged, so that the installation of the driving rotary disk is facilitated, the driving rotary disk is connected to the second motor, the rotation of the driving rotary rod can be driven, and corresponding power is provided for the rotation of the driving rotary rod.

Further, the driving rotary disc is connected with a driving rotary rod, so that the driven rotary ring can be driven to reciprocate, and the moving pre-crushing bin can reciprocate through the assistance of the reciprocating positioning shaft, so that the pre-crushing efficiency of graphite in the moving pre-crushing bin is improved;

the motion is smashed and is connected with driven swivel ring on the storehouse in advance, has received the drive of initiative rotary rod, makes the motion smash storehouse in advance and can carry out reciprocating motion, driven swivel ring is last to open has with initiative rotary rod assorted driven groove.

Further, the stable type buffering positioning mechanism comprises a pair of stable arc plates, so that the installation of the buffering air bag is facilitated, corresponding support is provided for the buffering air bag, and meanwhile, the stability of the reciprocating positioning shaft is improved;

the pair of stable arc plates are connected with the positioning mounting plate, so that the position of the positioning mounting plate can be fixed, and the stability of the positioning mounting plate is improved;

the support piece is connected between the stable arc plate and the graphite production furnace body, so that the stability of the stable arc plate is improved, the inclination or displacement probability of the stable arc plate is reduced, and the stability of the buffer air bag is correspondingly improved.

Further, a buffer air bag is connected between the stable arc plate and the motion pre-crushing bin, so that the motion pre-crushing bin can be buffered correspondingly, meanwhile, non-Newtonian fluid is contained, and the possibility of leakage of the non-Newtonian fluid is reduced;

the buffer air bag is internally connected with a pair of telescopic rods, the buffer air bag can be assisted to buffer the motion pre-crushing bin, the damage probability of the motion pre-crushing bin is reduced, the service life of the motion pre-crushing bin is prolonged, the buffer air bag is internally provided with non-Newtonian fluid, and the auxiliary buffer air bag is used for buffering the motion pre-crushing bin.

Further, both sides of the motion pre-crushing bin are connected with reciprocating positioning shafts, so that the sliding of the motion pre-crushing bin can be limited to a certain extent, the height of the motion pre-crushing bin is positioned, the motion pre-crushing bin can reciprocate, and the reciprocating positioning shafts penetrate through the buffer air bags and the stable arc plates.

Further, the rebound vibration anti-blocking mechanism comprises a communication pipeline, a corresponding channel is provided for the graphite production furnace body to enter the graphite, so that the graphite in the motion pre-crushing bin can enter the graphite production furnace body through the communication pipeline;

the leak-proof membrane is connected between the communicating pipeline and the motion pre-crushing bin, and the communicating pipeline and the motion pre-crushing bin are connected, so that the leakage of graphite is reduced, and the probability of graphite waste is reduced.

Furthermore, a pair of anti-blocking fixing rods are connected in the communicating pipeline, so that the installation of the impact block is facilitated, and the assistance is provided for fixing the position of the impact block;

the anti-blocking fixed rod is connected with the impact block, and when the pre-crushing bin moves to reciprocate, the anti-blocking blanking net collides with the impact block, so that the possibility of graphite clamping on the anti-blocking blanking net is reduced;

the rotary spring is connected between the impact block and the anti-blocking fixed rod, and can assist the impact block to adjust the position when the motion pre-crushing bin impacts the impact block, so that the probability of inclination of the impact block is reduced, and meanwhile, the damage of the impact block to the anti-blocking blanking net is reduced.

Compared with the prior art, the invention has the following advantages:

according to the invention, through the arrangement of the corresponding mechanism on the graphite production furnace, the graphite can be pre-crushed, the size can be more uniform, the heating speed is improved when the graphite is processed, the experimental efficiency of the graphite production furnace is improved, and meanwhile, the consumption of heat energy is reduced, so that the waste is reduced, and the environment is protected.

Drawings

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

FIG. 1 is a sectional view showing a first part of a construction of an intelligent environmental-friendly production furnace for graphite production in accordance with an embodiment of the invention;

FIG. 2 is a schematic diagram of the structure of FIG. 1 at A;

FIG. 3 is a schematic view of the structure of FIG. 1 at B;

FIG. 4 is a schematic view of the structure of FIG. 1 at C;

FIG. 5 is a sectional view showing a second part of the structure of an intelligent environmental-friendly production furnace for graphite production according to an embodiment of the invention;

FIG. 6 is a first perspective view of an intelligent environmental-friendly production furnace for graphite production in accordance with an embodiment of the invention;

FIG. 7 is a schematic view of the structure of FIG. 6 at D;

FIG. 8 is a second perspective view of an intelligent environmental-friendly production furnace for graphite production in accordance with an embodiment of the invention;

FIG. 9 is a schematic view of the structure of FIG. 8 at E; .

In the figure: 1. a graphite production furnace body, 2. A rotary cutting pre-crushing mechanism, 201. A moving pre-crushing bin, 202. A mounting shaft, 203. A pre-crushing cutter set, 204. A first motor, 205. A fixed cutting rod, 206. A feed bin, 207. An anti-blocking blanking screen, 3. A reciprocating efficiency-improving pre-crushing mechanism, 301. A positioning mounting plate, 302. A second motor, 303. A driving rotary disk, 304. A driving rotary rod, 305. A driven rotary ring, 4. A stable buffer positioning mechanism, 401. A stable arc plate, 402. A support, 403. A buffer air bag, 404. A telescopic rod, 405. A non-Newtonian fluid, 406. A reciprocating positioning shaft, 5. A rebound vibration anti-blocking mechanism, 501. A communicating pipe, 502. A leak-proof membrane, 503. An anti-blocking fixing rod, 504. An impact block, 505. A rotary spring.

Detailed Description

The present invention will be described in detail below with reference to the embodiments shown in the drawings. The embodiments are not intended to limit the invention, but structural, methodological or functional modifications from the embodiments are within the scope of the invention.

The invention discloses an intelligent environment-friendly production furnace for graphite production, which is shown with reference to figures 1-9 and comprises the following steps: the graphite production furnace comprises a graphite production furnace body 1, a rotary cutting pre-crushing mechanism 2, a reciprocating type efficiency improving pre-crushing mechanism 3, a stable buffering and positioning mechanism 4 and a rebound type vibration anti-blocking mechanism 5.

Referring to fig. 1-9, a rotary cutting pre-crushing mechanism 2 is arranged on a graphite production furnace body 1, the rotary cutting pre-crushing mechanism 2 comprises a moving pre-crushing bin 201, a corresponding space is provided for pre-crushing graphite, and pre-crushing of graphite by a pre-crushing cutter group 203 is facilitated.

Wherein, be equipped with installation axle 202 in the motion pre-crushing storehouse 201, made things convenient for the installation of pre-crushing cutting knife group 203, promoted the stability of pre-crushing cutting knife group 203, installation axle 202 can receive the drive of first motor 204 to rotate simultaneously.

In addition, the mounting shaft 202 is connected with a plurality of groups of pre-crushing cutter groups 203, so that graphite can be pre-crushed, and the sizes of the graphite tend to be uniform.

Referring to fig. 1 to 9, a first motor 204 is connected to the moving pre-crushing bin 201, and can drive the mounting shaft 202 to rotate, so that the pre-crushing cutter set 203 can be driven to rotate in the moving pre-crushing bin 201, and the pre-crushing cutter set 203 can pre-crush graphite.

The first motor 204 is disposed through the motion pre-crushing bin 201 and the mounting shaft 202, which facilitates the driving of the first motor 204 to the mounting shaft 202 and provides corresponding power for the rotation of the mounting shaft 202.

In addition, be connected with a plurality of fixed cutting bars 205 on the pre-crushing cutting knife group 203, not only can fix the pre-crushing cutting knife group 203, reduced the possibility that the pre-crushing cutting knife group 203 dispersed, can also assist the pre-crushing cutting knife group 203 to smash graphite, promoted the efficiency of graphite pre-crushing, fixed cutting bars 205 run through the setting of pre-crushing cutting knife group 203.

Referring to fig. 1-9, a feeding bin 206 is connected to the moving pre-crushing bin 201, and graphite can be fed from the position of the feeding bin 206, so that the moving pre-crushing bin 201 can be supplemented with graphite at any time, and the feeding bin 206 penetrates through the moving pre-crushing bin 201.

Optionally, the side of the motion pre-crushing bin 201 away from the feeding bin 206 is connected with an anti-blocking blanking net 207, so that the crushed graphite is conveniently discharged, and the graphite can enter the graphite production furnace body 1.

In other words, the blanking groove matched with the anti-blocking blanking net 207 is cut on the motion pre-crushing bin 201, so that the anti-blocking blanking net 207 is conveniently fixed, the stability of the anti-blocking blanking net 207 is improved, and the possibility that the anti-blocking blanking net 207 falls is reduced.

Referring to fig. 1-7, a reciprocating type efficiency improving pre-crushing mechanism 3 is arranged on one side of the motion pre-crushing bin 201 and is used for driving the motion pre-crushing bin 201 to shake, the reciprocating type efficiency improving pre-crushing mechanism 3 comprises a positioning mounting plate 301, the fixation of the second motor 302 is facilitated, and corresponding assistance is provided for the stability of the second motor 302.

In addition, the positioning mounting plate 301 is connected with a second motor 302, which can drive the rotation of the active rotating disk 303, and provides corresponding power for the rotation of the active rotating disk 303.

Optionally, the second motor 302 penetrates through the positioning mounting plate 301, so that the installation of the active rotating disc 303 is facilitated, the active rotating disc 303 is connected to the second motor 302, and the second motor 302 can drive the active rotating rod 304 to rotate, so that corresponding power is provided for the rotation of the active rotating rod 304.

Referring to fig. 1-7, a driving rotary rod 304 is connected to the driving rotary disk 303, and can drive the driven rotary ring 305 to reciprocate, so that the moving pre-crushing bin 201 reciprocates with the aid of the reciprocating positioning shaft 406, and the pre-crushing efficiency of graphite in the moving pre-crushing bin 201 is improved.

Preferably, the motion pre-crushing bin 201 is connected with a driven rotating ring 305, and is driven by a driving rotating rod 304, so that the motion pre-crushing bin 201 can reciprocate, and the driven rotating ring 305 is provided with a driven groove matched with the driving rotating rod 304.

Referring to fig. 1 to 3, a stable buffer positioning mechanism 4 is connected to the graphite production furnace body 1 for the stabilization of the lift motion pre-crushing bin 201, and the stable buffer positioning mechanism 4 includes a pair of stable arc plates 401, which facilitates the installation of the buffer air bag 403, provides corresponding support for the buffer air bag 403, and promotes the stability of the reciprocating positioning shaft 406.

The pair of stable arc plates 401 are connected with the positioning mounting plate 301, so that the position of the positioning mounting plate 301 can be fixed, and the stability of the positioning mounting plate 301 is improved.

In addition, be connected with support piece 402 between stable arc board 401 and the graphite production furnace body 1, promoted stable arc board 401's stability, reduced stable arc board 401 slope or the probability of displacement, made the corresponding promotion of stability of buffering gasbag 403.

Referring to fig. 1-3, a buffer air bag 403 is connected between the stabilizing arc plate 401 and the motion pre-crushing bin 201, so that the motion pre-crushing bin 201 can be buffered correspondingly, and meanwhile, the non-newtonian fluid 405 is contained, so that the possibility of leakage of the non-newtonian fluid 405 is reduced.

Preferably, a pair of telescopic rods 404 are connected to the buffer air bag 403, so that the buffer air bag 403 can be assisted to buffer the motion pre-crushing bin 201, the damage probability of the motion pre-crushing bin 201 is reduced, the service life of the motion pre-crushing bin 201 is prolonged, and a non-Newtonian fluid 405 is arranged in the buffer air bag 403, so that the motion pre-crushing bin 201 is buffered by the auxiliary buffer air bag 403.

Referring to fig. 1 to 3, the reciprocating positioning shafts 406 are connected to both sides of the moving pre-crushing bin 201, so that the sliding of the moving pre-crushing bin 201 can be limited to a certain extent, the height of the moving pre-crushing bin 201 is positioned, the moving pre-crushing bin 201 can reciprocate, and the reciprocating positioning shafts 406 penetrate through the buffer air bags 403 and the stabilizing arc plates 401.

Referring to fig. 1-4, a rebound vibration anti-blocking mechanism 5 is connected to a graphite production furnace body 1, and is used for reducing the blocking of graphite, the rebound vibration anti-blocking mechanism 5 comprises a communication pipeline 501, a corresponding channel is provided for the graphite production furnace body 1 to enter the graphite, and the graphite in the motion pre-crushing bin 201 can enter the graphite production furnace body 1 through the communication pipeline 501.

In addition, be connected with leak protection membrane 502 between communicating pipe 501 and the motion pre-crushing storehouse 201, connected communicating pipe 501 and motion pre-crushing storehouse 201, reduced the leakage of graphite, make the extravagant probability of graphite reduce.

Referring to fig. 1-9, a pair of anti-blocking fixing rods 503 are connected to the communicating pipe 501, which facilitates the installation of the impact block 504 and helps to fix the position of the impact block 504.

Optionally, the anti-blocking fixing rod 503 is connected with the impact block 504, when the pre-crushing bin 201 moves to reciprocate, the anti-blocking blanking net 207 collides with the impact block 504, so that the possibility of graphite clamping on the anti-blocking blanking net 207 is reduced.

Preferably, a rotary spring 505 is connected between the impact block 504 and the anti-blocking fixing rod 503, when the motion pre-crushing bin 201 impacts the impact block 504, the rotary spring 505 can assist the impact block 504 to adjust the position, so that the probability of tilting the impact block 504 is reduced, and meanwhile, the damage of the impact block 504 to the anti-blocking blanking net 207 is reduced.

Specifically, the user pours graphite of different sizes from the feeding bin 206 into the motion pre-crushing bin 201, and starts the first motor 204 and the second motor 302, so that the installation shaft 202 can drive the pre-crushing cutter group 203 to rotate, and the graphite is pre-crushed through the pre-crushing cutter group 203 and the fixed cutting rod 205, so that the graphite size can tend to be uniform, and more efficient production is realized.

In synchronization, the second motor 302 drives the driving rotary disk 303 to move, and the driving rotary rod 304 drives the driven rotary ring 305 to enable the moving pre-crushing bin 201 to reciprocate, so that the graphite in the moving pre-crushing bin 201 is better crushed by the pre-crushing cutter group 203 and the fixed cutting rod 205 in the reciprocating process, and the pre-crushing efficiency of the graphite is improved.

In addition, stable type buffering positioning mechanism 4 can cushion motion pre-crushing storehouse 201, not only can promote the pre-crushing efficiency of graphite, can also reduce the damage that motion pre-crushing storehouse 201 received, impact piece 504 in the mutual striking with prevent stifled unloading net 207, can shake down the graphite of block on preventing stifled unloading net 207, has reduced the probability that graphite blockked up.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment contains only one independent technical solution, and that such description is provided for clarity only, and that the technical solutions of the embodiments may be appropriately combined to form other embodiments that will be understood by those skilled in the art.

Claims (3)

1. An intelligent environmental protection type production furnace for graphite production, which is characterized by comprising:

a graphite production furnace body (1);

the rotary type cutting pre-crushing mechanism (2) is arranged on the graphite production furnace body (1), the rotary type cutting pre-crushing mechanism (2) comprises a moving pre-crushing bin (201), a mounting shaft (202) is arranged in the moving pre-crushing bin (201), and a plurality of groups of pre-crushing cutter groups (203) are connected to the mounting shaft (202);

the reciprocating type efficiency-improving pre-crushing mechanism (3) is arranged on one side of the motion pre-crushing bin (201) and is used for driving the motion pre-crushing bin (201) to shake;

the stable type buffering and positioning mechanism (4) is connected to the graphite production furnace body (1) and used for stabilizing the lifting movement pre-crushing bin (201);

the rebound vibration anti-blocking mechanism (5) is connected to the graphite production furnace body (1) and is used for reducing the blocking of graphite; the motion pre-crushing bin (201) is connected with a first motor (204), the first motor (204) penetrates through the motion pre-crushing bin (201) and the installation shaft (202), the pre-crushing cutter group (203) is connected with a plurality of fixed cutting rods (205), and the fixed cutting rods (205) penetrate through the pre-crushing cutter group (203); the feeding bin (206) is connected to the motion pre-crushing bin (201), the feeding bin (206) penetrates through the motion pre-crushing bin (201), an anti-blocking blanking net (207) is connected to one side, away from the feeding bin (206), of the motion pre-crushing bin (201), and a blanking groove matched with the anti-blocking blanking net (207) is cut on the motion pre-crushing bin (201); the reciprocating type efficiency improving pre-crushing mechanism (3) comprises a positioning mounting plate (301), wherein a second motor (302) is connected to the positioning mounting plate (301), the second motor (302) penetrates through the positioning mounting plate (301), and an active rotating disc (303) is connected to the second motor (302); the driving rotary disc (303) is connected with a driving rotary rod (304), the motion pre-crushing bin (201) is connected with a driven rotary ring (305), and the driven rotary ring (305) is provided with a driven groove matched with the driving rotary rod (304); the stable type buffering positioning mechanism (4) comprises a pair of stable arc plates (401), the pair of stable arc plates (401) are connected with the positioning mounting plate (301), and a supporting piece (402) is connected between the stable arc plates (401) and the graphite production furnace body (1); a buffer air bag (403) is connected between the stable arc plate (401) and the motion pre-crushing bin (201), a pair of telescopic rods (404) are connected in the buffer air bag (403), and a non-Newtonian fluid (405) is arranged in the buffer air bag (403); both sides of the motion pre-crushing bin (201) are connected with a reciprocating positioning shaft (406), and the reciprocating positioning shaft (406) penetrates through the buffer air bag (403) and the stabilizing arc plate (401).

2. The intelligent environment-friendly production furnace for graphite production according to claim 1, wherein the rebound vibration anti-blocking mechanism (5) comprises a communication pipeline (501), and a leakage-proof film (502) is connected between the communication pipeline (501) and the motion pre-crushing bin (201).

3. The intelligent environment-friendly production furnace for graphite production according to claim 2, wherein a pair of anti-blocking fixing rods (503) are connected to the communicating pipeline (501), impact blocks (504) are connected to the anti-blocking fixing rods (503), and rotary springs (505) are connected between the impact blocks (504) and the anti-blocking fixing rods (503).