CN217621472U - Graphite anode special-shaped part cutting device - Google Patents

Abstract

The application provides a graphite anode dysmorphism cutting device includes: the upper surface of the support table is vertically provided with two first baffles which are parallel to each other along the length direction of the upper surface, a first fixing rod which is perpendicular to the two first baffles is fixedly arranged between the two first baffles, and a second fixing rod which is parallel to the first fixing rod is arranged between the two first baffles in a sliding manner; the clamping assembly comprises a lower clamping part, a first upper clamping part, a second upper clamping part and an end clamping part; the lower clamping part is arranged on the upper surface of the supporting table and is positioned between the two first baffles, the first upper clamping part is arranged on the first fixed rod, and the second upper clamping part is arranged on the second fixed rod; the end clamping part is arranged on the side surface of the supporting platform; the cutting assembly is arranged on the supporting platform. This application has realized waiting to cut diversified fixed of graphite anode, has avoided waiting to cut graphite anode among the cutting process and has taken place axial drunkenness, has improved the stability and the cutting precision among the cutting process of waiting to cut graphite anode.

Description

Graphite anode special-shaped piece cutting device

Technical Field

The application relates to a graphite anode dysmorphism cutting technology especially relates to a graphite anode dysmorphism cutting device.

Background

The graphite anode is a graphite plate, block or bar used as an anode of an electrolytic cell in the electrolysis industry, and refers to a high-temperature resistant graphite conductive material which is made by using petroleum coke and pitch coke as aggregates and coal pitch as an adhesive through the steps of raw material calcination, crushing and grinding, blending, kneading, molding, roasting, impregnation, graphitization and machining, and is called an artificial graphite electrode (graphite electrode for short), and a special-shaped piece is a workpiece with an irregularly distributed outer edge surface and cannot be made of copper, but graphite is easy to mold, so the graphite anode is mostly used as a raw material for producing the special-shaped graphite anode piece, and particularly, the graphite anode is cut into a required shape to obtain the special-shaped graphite anode piece.

The existing cutting device only fixes the bottom of the graphite anode to be cut, so that the graphite anode can generate axial movement in the cutting process, the stability of the graphite electrode in the machining process cannot be ensured, the machining precision is influenced, the graphite has certain brittleness, and the graphite electrode can be crushed if only the bottom of the graphite anode to be cut is fixed.

SUMMERY OF THE UTILITY MODEL

The application provides a graphite anode dysmorphism a cutting device for solve current cutting device for graphite electrode and only treat the bottom of cutting graphite and fix, make graphite can produce axial drunkenness in cutting process, can't guarantee the stability of graphite electrode in the course of working, and then influence the precision of processing, and graphite has certain fragility, only treats the bottom of cutting graphite and fixes the problem that probably crushes the graphite electrode.

In order to solve the technical problem, the application adopts the following technical scheme to realize:

the application provides a graphite anode special-shaped part cutting device which comprises a supporting table, a clamping assembly and a cutting assembly;

the upper surface of the supporting table is vertically provided with two first baffles which are parallel to each other along the length direction of the supporting table, a first fixing rod which is perpendicular to the two first baffles is fixedly arranged between the two first baffles, and a second fixing rod which is parallel to the first fixing rod is arranged between the two first baffles in a sliding manner;

the clamping assembly comprises a lower clamping part, a first upper clamping part, a second upper clamping part and an end clamping part; the lower clamping part is arranged on the upper surface of the supporting table and is positioned between the two first baffles, the first upper clamping part is arranged on the first fixed rod, the second upper clamping part is arranged on the second fixed rod, and the lower clamping part, the first upper clamping part and the second upper clamping part are matched with each other and are used for clamping the graphite anode to be cut up and down; the end clamping part is arranged on the side surface of the supporting table and is used for clamping the end of the graphite anode to be cut;

the cutting assembly is arranged on the supporting table and used for cutting the graphite anode to be cut after clamping.

Optionally, two first sliding chutes are arranged in parallel on the upper surface of the support table along the length direction of the upper surface, and the two first sliding chutes are located between the two first baffles;

the lower clamping part comprises a first U-shaped supporting block with an upward opening and a second U-shaped supporting block with an upward opening;

the first U-shaped supporting block is fixedly arranged between the two first baffle plates on the upper surface of the supporting platform;

the lower surface of the second U-shaped supporting block is provided with first sliding blocks which are respectively matched with the two first sliding grooves, and the first sliding blocks slide along the length direction of the first sliding grooves;

the first U-shaped supporting block and the second U-shaped supporting block are located on the same straight line.

Optionally, a plurality of upper fixing grooves are formed in each of the first U-shaped supporting block and the second U-shaped supporting block, a first fixing shaft is arranged in each of the upper fixing grooves, and a plurality of first ball bearings abutted against the outer surface of the graphite anode to be cut are sleeved on each of the first fixing shafts;

and a first vibration reduction layer is arranged on the peripheral wall of each first ball bearing.

Optionally, the two first baffles are respectively provided with a second sliding chute along the length direction thereof, and two ends of the second fixed rod are respectively provided with a second sliding block matched with the two second sliding chutes;

the first upper clamping part and the second upper clamping part respectively comprise a first electric push rod and a third U-shaped supporting block with a downward opening;

one of the electric push rods is vertically and downwards arranged on the first fixing rod, the other electric push rod is vertically and downwards arranged on the second fixing rod, and the output end of each first electric push rod is provided with one third U-shaped supporting block.

Optionally, a plurality of lower fixing grooves are formed in each third U-shaped supporting block, a second fixing shaft is arranged in each lower fixing groove, and a plurality of second ball bearings abutted against the outer surface of the graphite anode to be cut are sleeved on each second fixing shaft;

and a second vibration reduction layer is arranged on the peripheral wall of each second ball bearing.

Optionally, the end clamping part comprises an L-shaped supporting plate, a first threaded rod, a second baffle and a first driving motor;

the L-shaped support plate is fixed on the side wall of the support table, a first threaded through hole is formed in the L-shaped support plate, the first threaded rod penetrates through the first threaded through hole and is in threaded connection with the L-shaped support plate, a second baffle is arranged at one end, close to the clamping assembly, of the first threaded rod, and the other end of the first threaded rod is connected with an output shaft of the first driving motor fixed on the side wall of the support table;

and a third vibration reduction layer is arranged on one surface of the second baffle, which is abutted to the graphite electrode to be cut.

Optionally, each first baffle is provided with a third sliding chute along the length direction thereof, and the third sliding chute is located above the second sliding chute;

the cutting assembly comprises a sliding plate, a second electric push rod and a cutting knife;

the two sides of the sliding plate correspond to the two third sliding grooves one by one and are inserted into the third sliding grooves, a second electric push rod is arranged at the bottom of the sliding plate, the output end of the second electric push rod is connected with the cutting knife, and the second electric push rod is used for driving the cutting knife to move up and down relative to the graphite anode to be cut.

Optionally, the graphite anode profile cutting device provided by the present application further includes a driving assembly;

the driving assembly comprises a fixing plate, a second threaded rod, a second driving motor, a third electric push rod and a push plate;

the fixed plate is relative the end clamping part sets up the other end of brace table, the second screw thread through-hole has been seted up on the fixed plate, the second threaded rod passes through the second screw thread through-hole with fixed plate threaded connection, the bottom of second threaded rod is in with the setting the output shaft of the second driving motor on the brace table, the top fixed plate of second threaded rod is provided with third electric putter, third electric putter's output is kept away from the top of second threaded rod and is provided with the push pedal.

Optionally, a flow gathering hole with a large upper part and a small lower part is formed in the supporting table, the flow gathering hole is located between the first sliding grooves, an upper opening collecting box is arranged at the bottom of the flow gathering hole, the upper opening of the collecting box is right opposite to the bottom of the flow gathering hole, and the caliber of the upper opening of the collecting box is larger than the caliber of the lower opening of the flow gathering hole.

Optionally, a support column is arranged on the lower surface of the support table, the top of the support column is connected with the lower surface of the support table, and a pulley is arranged at the bottom of the support column.

The utility model provides a graphite anode dysmorphism cutting device, through the lower clamping part that sets up on the upper surface of brace table with set up the first clamping part of going up on first dead lever and set up the second on the second dead lever and go up the clamping part, wherein, the second dead lever slides and sets up between two first baffles, and then can realize the graphite anode that waits to cut to co-altitude on, stabilize fixedly down, rethread tip clamping part is fixed the graphite anode's of waiting to cut of different length tip, realized waiting to cut graphite anode on, down and the fixed of tip, it takes place axial drunkenness to have avoided waiting to cut graphite anode among the cutting process, stability and cutting precision among the cutting process of waiting to cut graphite anode have been improved, finally can obtain the graphite anode dysmorphism that accords with the standard.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following descriptions are some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural diagram of a graphite anode profile cutting device according to an embodiment of the present disclosure;

fig. 2 is a schematic view of an internal structure of a graphite anode profile cutting device according to another embodiment of the present application;

FIG. 3 is a schematic view of a second U-shaped support block according to another embodiment of the present application;

FIG. 4 is a cross-sectional view of a right side view of a second U-shaped support block provided in another embodiment of the present application.

In the figure: 100. a support table; 101. a first baffle; 102. a first chute; 103. a flow gathering hole; 104. A support pillar; 1041. a pulley; 200. a first U-shaped support block; 201. an upper fixing groove; 202. a first fixed shaft; 203. a first ball bearing; 300. a second U-shaped support block; 400. a first upper clamping portion; 401. a first fixing lever; 402. a first electric push rod; 403. a third U-shaped support block; 4031. a lower fixing groove; 4032. a second ball bearing; 500. a second upper clamping portion; 501. a second chute; 502. a second fixing bar; 600. an end clamping part; 601. a first drive motor; 602. a first threaded rod; 603. an L-shaped support plate; 604. a second baffle; 700. a cutting assembly; 701. a third chute; 702. a sliding plate; 703. a second electric push rod; 704. a cutting knife; 800. a drive assembly; 801. a second drive motor; 802. a fixing plate; 803. a second threaded rod; 804. a third electric push rod; 805. pushing the plate; 900. a material collecting box; 1000. the graphite anode is to be cut.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application are clearly and completely described below, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without making any creative effort also belong to the protection scope of the present application.

Referring to fig. 1 to 4, the present application provides a graphite anode irregular member cutting device, which includes a supporting table 100, a clamping assembly and a cutting assembly 700, wherein the supporting table 100 is used for supporting the clamping assembly and the cutting assembly 700.

The upper surface of the supporting table 100 is vertically provided with two first baffles 101 which are parallel to each other along the length direction thereof, a first fixing rod 401 which is perpendicular to the two first baffles 101 is fixedly arranged between the two first baffles 101, a second fixing rod 502 which is parallel to the first fixing rod 401 is slidably arranged between the two first baffles 101, wherein two ends of the second fixing rod 502 can slide on the first baffles 101 along the length direction of the first baffles 101.

The clamping assembly comprises a lower clamping portion, a first upper clamping portion 400, a second upper clamping portion 500 and a tip clamping portion 600; the lower clamping part is arranged on the upper surface of the support table 100 and is positioned between the two first baffles 101, the first upper clamping part 400 is arranged on the first fixing rod 401, the second upper clamping part 500 is arranged on the second fixing rod 502, and the lower clamping part, the first upper clamping part 400 and the second upper clamping part 500 are mutually matched for clamping the graphite anode 1000 to be cut up and down; end clamping part 600 sets up the side at brace table 100 for treat the end of cutting graphite anode 1000 and carry out the centre gripping, wherein, clamping part 500 sets up on second dead lever 502 on the second, along with second dead lever 502 slides back and forth along the length direction of two first baffles 101 between two first baffles 101, and then through lower clamping part, first last clamping part 400, clamping part 500 and end clamping part 600 on the second, realize treating the all-round fixed of cutting graphite anode 1000, avoid treating in the cutting process and cut graphite anode 1000 and take place the axial float, and then improved the stability and the cutting precision of treating cutting graphite anode 1000 in the cutting process, make the graphite anode dysmorphism piece that obtains after the cutting accord with the service standard.

Cutting assembly 700 sets up on a supporting bench 100 for treating behind the centre gripping and cutting graphite anode 1000 and cutting, treat through cutting assembly 700 and cut graphite anode 1000 cutting back, obtain graphite anode dysmorphism piece, wherein, cutting assembly 700 cuts the graphite anode and obtains graphite anode dysmorphism piece and is prior art, and this application has solved the problem of the unable stability of guaranteeing graphite electrode in the course of working of current cutting device, has improved graphite anode dysmorphism piece's rate of adaptation.

In some embodiments, the upper surface of the support table 100 in the present application is provided with two first sliding chutes 102 in parallel along the length direction thereof, and the two first sliding chutes 102 are located between the two first baffles 101, wherein the length of the first sliding chute 102 is smaller than the length of the support table 100.

The lower clamping part comprises a first U-shaped supporting block 200 with an upward opening and a second U-shaped supporting block 300 with an upward opening; the first U-shaped supporting block 200 is fixedly disposed between the two first baffles 101 on the upper surface of the supporting table 100; the lower surface of the second U-shaped supporting block 300 is provided with first sliding blocks respectively matched with the two first sliding grooves 102, and the first sliding blocks slide along the length direction of the first sliding grooves 102; the first U-shaped supporting block 200 and the second U-shaped supporting block 300 are located on a straight line, wherein the first slider can be manually operated to slide back and forth in the first sliding groove 102 along the length direction of the first sliding groove 102 according to the length of the graphite anode 1000 to be cut, so that the first U-shaped supporting block 200 and the second U-shaped supporting block 300 fix the bottom of the graphite anode 1000 to be cut.

In some embodiments, a plurality of upper fixing grooves 201 are formed in each of the first U-shaped support block 200 and the second U-shaped support block 300, wherein the openings of the upper fixing grooves 201 face upward, a first fixing shaft 202 is disposed in each of the upper fixing grooves 201, and a plurality of first ball bearings 203 abutted to the outer surface of the graphite anode 1000 to be cut are sleeved on each of the first fixing shafts 202, wherein the first ball bearings 203 are rotatably connected to the first fixing shafts 202, so that the first ball bearings 203 can rotate around the first fixing shafts 202, and because graphite is brittle, when the graphite anode rotates or deviates during cutting, the friction between the graphite anode 1000 to be cut and the upper fixing grooves 201 is reduced, the stability of the cutting process is improved, and a graphite anode special-shaped part can be obtained quickly.

Be provided with first damping layer on every first ball bearing 203's the periphery wall, wherein, first damping layer can be the rubber or the silica gel material that elasticity is higher, reduces the frictional force when waiting to cut graphite anode and first ball bearing 203 contact and the pressure that the lower surface of waiting to cut graphite anode 1000 brought of first ball bearing 203's surface for wait to cut graphite anode 1000 cutting in-process difficult fracture, increased cutting process's stability.

In the above embodiments, the structure of the second U-shaped supporting block is the same as that of the first U-shaped supporting block, that is, the structural schematic diagram of the second U-shaped supporting block can refer to fig. 3 to 4.

In some embodiments, the two first baffles 101 in the present application are both provided with the second sliding grooves 501 along the length direction thereof, and the two ends of the second fixing rod 502 are respectively provided with the second sliding blocks matched with the two second sliding grooves 501, wherein the second fixing rod 502 can slide along the length direction of the second sliding grooves 501, and can fix the top of the graphite anode 1000 to be cut according to the length of the graphite anode 1000 to be cut.

The first upper clamping part 400 and the second upper clamping part 500 respectively comprise a first electric push rod 402 and a third U-shaped supporting block 403 with a downward opening; one electric push rod 402 is vertically downwards arranged on the first fixing rod 401, the other electric push rod 402 is vertically downwards arranged on the second fixing rod 502, the output end of each first electric push rod 402 is provided with a third U-shaped supporting block 403, one third U-shaped supporting block 403 is right opposite to the first U-shaped supporting block 200, the other third U-shaped supporting block 403 is right opposite to the second U-shaped supporting block 300, the lower fixing grooves 4031 are respectively right opposite to the two upper fixing grooves 201, the distance between one third U-shaped supporting block 403 and the first U-shaped supporting block 200 and the distance between the other third U-shaped supporting block 403 and the second U-shaped supporting block 300 are adjusted through the first electric push rod 402 according to the thickness or the height of the graphite anode 1000 to be cut, and finally the graphite anode 1000 to be cut is stably fixed up and down through one third U-shaped supporting block 403 and the first U-shaped supporting block 200 and the other third U-shaped supporting block 403 and the second U-shaped supporting block 300.

In some embodiments, each third U-shaped support block 403 in the present application is provided with a plurality of lower fixing grooves 4031, wherein an opening of the lower fixing groove 4031 is downward, a plurality of second fixing shafts are disposed in each lower fixing groove 4031, each second fixing shaft is sleeved with a plurality of second ball bearings 4032 abutted to an outer surface of the graphite anode 1000 to be cut, wherein the second ball bearings 4032 are rotatably connected to the second fixing shafts, so that the second ball bearings 4032 can rotate around the second fixing shafts, and because graphite is brittle, when the second ball bearings 4032 can rotate around the second fixing shafts, so that the graphite anode rotates or deviates during cutting, friction between the graphite anode 1000 to be cut and the lower fixing groove 4031 is reduced, stability of the cutting process is improved, and a graphite anode special-shaped member can be quickly obtained.

Be provided with the second damping layer on every second ball bearing 4032's the periphery wall, wherein, the second damping layer can be the rubber or the silica gel material that elasticity is higher, reduces the frictional force when waiting to cut graphite anode 1000 and second ball bearing 4032 contact and the pressure that the upper surface of second ball bearing 4032 brought is treated to cutting graphite anode 1000's surface for difficult fracture in the graphite anode 1000 cutting process of waiting to cut has increased the stability of cutting process.

In some embodiments, the tip holder 600 in the present application includes an L-shaped support plate 603, a first threaded rod 602, a second stop plate 604, and a first drive motor 601; the L-shaped supporting plate 603 is fixed on the side wall of the supporting table 100, a first threaded through hole is formed in the L-shaped supporting plate 603, the first threaded rod 602 penetrates through the first threaded through hole and is in threaded connection with the L-shaped supporting plate 603, a second baffle 604 is arranged at one end, close to the clamping component, of the first threaded rod 602, the other end of the first threaded rod 602 is connected with an output shaft of a first driving motor 601 fixed on the side wall of the supporting table 100, the first threaded rod 602 is driven to move left and right in the first threaded through hole in the L-shaped supporting plate 603 through the first driving motor 601, the distance between the second baffle 604 and the end of the graphite anode 1000 to be cut is adjusted according to the length of the graphite anode 1000 to be cut, the second baffle 604 is abutted to the end of the graphite anode 1000 to be cut, and further fixes the end of the graphite anode 1000 to be cut, the stability of clamping of the graphite anode 1000 to be cut is further improved, the cutting is convenient to cut, and the cutting efficiency is further improved.

Second baffle 604 is provided with the third damping layer with the one side of waiting to cut graphite anode 1000 butt, wherein, the third damping layer can be the rubber or the silica gel material that elasticity is higher, reduces frictional force and the surface of second baffle 604 when waiting to cut graphite anode 1000's tip and second baffle 604 contact and treats the pressure that the tip of cutting graphite anode 1000 brought, makes to wait to cut graphite anode 1000 difficult fracture in the cutting process, has increased the stability of cutting process.

In the above embodiments, the structure of the third U-shaped supporting block is the same as that of the first U-shaped supporting block, that is, the structural schematic diagram of the third U-shaped supporting block can refer to fig. 3 to 4.

In some embodiments, each first baffle 101 in the present application is provided with a third sliding chute 701 along a length direction thereof, and the third sliding chute 701 is located above the second sliding chute 501; the cutting assembly 700 comprises a sliding plate 702, a second electric push rod 703 and a cutting knife 704; the two sides of the sliding plate 702 correspond to the two third sliding grooves 701 one by one and are inserted into the third sliding grooves 701, the bottom of the sliding plate 702 is provided with a second electric push rod 703, the output end of the second electric push rod 703 is connected with a cutting knife 704, the second electric push rod 703 is used for driving the cutting knife 704 to move up and down relative to the graphite anode 1000 to be cut, wherein, a worker can manually make the sliding plate 702 slide in the third sliding grooves 701, and adjust the bottom distance of the cutting knife 704 through the second electric push rod 703 to adjust the distance of the graphite anode 1000 to be cut, the distance between the cutting head 704 and the graphite anode 1000 to be cut can be adjusted according to the length and height of the graphite anode 1000 to be cut, accurate cutting of the graphite anode 1000 to be cut is realized, the cutting time is shortened, and the cutting efficiency is further improved.

In some embodiments, the graphite anode profile cutting apparatus of the present application further comprises a drive assembly 800; the driving assembly 800 comprises a fixing plate 802, a second threaded rod 803, a second driving motor 801, a third electric push rod 804 and a push plate 805; the opposite end clamping part 600 of fixed plate 802 sets up the other end at a supporting bench 100, the second screw through-hole has been seted up on fixed plate 802, second threaded rod 803 passes through second screw through-hole and fixed plate 802 threaded connection, the bottom of second threaded rod 803 and the output shaft of the second driving motor 801 of setting on a supporting bench 100, the top of second threaded rod 803 is provided with third electric putter 804, the top of second threaded rod 803 is kept away from to the output of third electric putter 804 and is provided with push pedal 805, wherein, it reciprocates in the second screw through-hole on fixed plate 802 to drive second threaded rod 803 through second driving motor 801, and move about push pedal 805 of the flexible regulation connection on the output of third electric putter 804 through third electric putter 804.

Specifically, before cutting, the second U-shaped supporting block 300 is located at the rightmost end of the first sliding groove 102, the second fixing rod 502 is located at the rightmost end of the second sliding groove 501, the sliding plate 702 is located at the rightmost end of the third sliding groove 701, when the length of the graphite anode 1000 to be cut is smaller than the length of the first sliding groove 102, the second driving motor 801 is firstly opened, the second threaded rod 803 rotates in the second threaded through hole, when the pushing plate 805 is opposite to the second U-shaped supporting block 300, the second driving motor 801 is closed, the third electric push rod 804 is opened, the pushing plate 805 opposite to the second U-shaped supporting block 300 is pushed by the third electric push rod 804 to push the second U-shaped supporting block 300 to slide leftwards along the first sliding groove 102 until the distance between the first U-shaped supporting block 200 and the second U-shaped supporting block 300 is smaller than the length of the graphite anode 1000 to be cut, and the third electric push rod 804 is closed; then, the second driving motor 801 is opened, so that the second threaded rod 803 rotates in the second threaded through hole, when the pushing plate 805 faces the second fixing rod 502, the second driving motor 801 is closed, the third electric push rod 804 is opened, the second fixing rod 502 is pushed by the third electric push rod 804 to slide in the second sliding groove 501 until the distance between the third U-shaped support block 403 at the output end of the first electric push rod 402 connected with the second fixing rod 502 and the other third U-shaped support block 403 is smaller than the length of the graphite anode 1000 to be cut, and the third electric push rod 804 is closed; the graphite electrode to be cut is vertically fixed through one of the third U-shaped supporting block 403 and the first U-shaped supporting block 200, and the other third U-shaped supporting block 403 and the second U-shaped supporting block 300, after the graphite electrode to be cut is fixed, the second driving motor 801 is turned on, so that the second threaded rod 803 rotates in the second threaded through hole, when the pushing plate 805 faces the sliding plate 702, the second driving motor 801 is turned off, the second electric push rod 703 is turned on, the sliding plate 702 is pushed by the second electric push rod 703 to slide in the third sliding groove 701 until the cutting knife 704 connected to the bottom end of the second electric push rod 703 on the lower surface of the sliding plate 702 faces the area to be cut of the graphite electrode 1000, the second driving motor 801 is turned off, the second electric push rod is turned on until the cutting knife 704 connected to the bottom end of the second electric push rod 703 abuts against the graphite electrode 1000 to be cut, during the cutting process, the telescopic length of the second electric push rod 703 is continuously adjusted according to the cutting depth of the cutting, after the cutting is completed, the graphite anode 703 is obtained, manual operation is avoided, the manual operation, the operation is further, the graphite anode 703 is simple and the accurate cutting is more convenient, and the accurate cutting of the graphite anode is improved.

In some embodiments, a flow gathering hole 103 with a large upper part and a small lower part is formed in the support table 100, the flow gathering hole 103 is located between the two first sliding grooves 102, a collecting box 900 with an upper opening is arranged at the bottom of the flow gathering hole 103, the upper opening of the collecting box 900 faces the bottom of the flow gathering hole 103, and the aperture of the upper opening of the collecting box 900 is larger than the aperture of the lower opening of the flow gathering hole 103, wherein the apertures of the upper openings of the flow gathering hole 103 and the collecting box 900 are larger than the aperture of the lower opening of the flow gathering hole 103, so that graphite anode slag generated in the cutting process can quickly fall into the collecting box 900, the graphite anode slag generated in the cutting process is prevented from being accumulated on the support table 100 to affect cutting, and the cutting efficiency is improved.

In some embodiments, the lower surface of the support table 100 in the application is provided with the support column 104, the top of the support column 104 is connected with the lower surface of the support table 100, and the bottom of the support column 104 is provided with the pulley 1041, so that the support table 100 can be conveniently moved according to the place where the graphite anode 1000 to be cut is located, the graphite anode 1000 to be cut is prevented from being carried to the vicinity of the support table 100, manpower is saved, and the cutting time is shortened.

The specific application method of the graphite anode special-shaped piece cutting device disclosed by the application is as follows:

1) After the components of the graphite anode special-shaped part cutting device are installed, a graphite anode 1000 to be cut is placed on the upper fixing groove 201, the second driving motor 801 is opened, the second driving motor 801 drives the second threaded rod 803 to move in a second threaded through hole in the fixing plate 802, the height of a third electric push rod 804 at the top end of the second threaded rod 803 is adjusted, the distance between a push plate 805 and the upper fixing groove 201 and the distance between a cutting knife 704 and the graphite anode 1000 to be cut are adjusted through the third electric push rod 804, the distance between the bottom of the first electric push rod 402 and the top of the graphite anode 1000 to be cut is adjusted through the first electric push rod 402, and the graphite anode 1000 to be cut is fixed up and down through the upper fixing groove 201 and the lower fixing groove 4031; and then, opening the first driving motor 601, driving the first threaded rod 602 to move in the first threaded through hole on the L-shaped supporting plate 603 through the first driving motor 601, so that the second baffle 604 on the first threaded rod 602 is abutted to the end of the graphite anode 1000 to be cut, and the end of the graphite anode 1000 to be cut is fixed.

2) And opening the third electric push rod 804, adjusting the distance between the cutting knife 704 and the graphite anode 1000 to be cut, and realizing the accurate cutting of the graphite anode 1000 to be cut.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art; the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present application.

Claims (10)

1. A graphite anode special-shaped piece cutting device is characterized by comprising a supporting table (100), a clamping assembly and a cutting assembly (700);

the upper surface of the support table (100) is vertically provided with two first baffles (101) which are parallel to each other along the length direction of the upper surface, a first fixing rod (401) which is perpendicular to the two first baffles (101) is fixedly arranged between the two first baffles (101), and a second fixing rod (502) which is parallel to the first fixing rod (401) is arranged between the two first baffles (101) in a sliding manner;

the clamping assembly comprises a lower clamping part, a first upper clamping part (400), a second upper clamping part (500) and an end clamping part (600); the lower clamping part is arranged on the upper surface of the support table (100) and is positioned between the two first baffles (101), the first upper clamping part (400) is arranged on the first fixing rod (401), the second upper clamping part (500) is arranged on the second fixing rod (502), and the lower clamping part, the first upper clamping part (400) and the second upper clamping part (500) are matched with each other to clamp the graphite anode (1000) to be cut up and down; the end head clamping part (600) is arranged on the side surface of the supporting table (100) and is used for clamping the end head of the graphite anode (1000) to be cut;

the cutting assembly (700) is arranged on the support table (100) and used for cutting the clamped graphite anode (1000) to be cut.

2. The graphite anode profile cutting device according to claim 1, characterized in that the upper surface of the support table (100) is provided with two first chutes (102) in parallel along the length direction thereof, and the two first chutes (102) are located between the two first baffles (101);

the lower clamping part comprises a first U-shaped supporting block (200) with an upward opening and a second U-shaped supporting block (300) with an upward opening;

the first U-shaped supporting block (200) is fixedly arranged between the two first baffle plates (101) on the upper surface of the supporting platform (100);

the lower surface of the second U-shaped supporting block (300) is provided with first sliding blocks which are respectively matched with the two first sliding grooves (102), and the first sliding blocks slide along the length direction of the first sliding grooves (102);

the first U-shaped supporting block (200) and the second U-shaped supporting block (300) are located on the same straight line.

3. The graphite anode profile cutting device according to claim 2, wherein a plurality of upper fixing grooves (201) are formed in each of the first U-shaped supporting block (200) and the second U-shaped supporting block (300), a first fixing shaft (202) is arranged in each upper fixing groove (201), and a plurality of first ball bearings (203) abutted with the outer surface of the graphite anode (1000) to be cut are sleeved on each first fixing shaft (202);

and a first vibration reduction layer is arranged on the peripheral wall of each first ball bearing (203).

4. The graphite anode special-shaped piece cutting device according to claim 2, characterized in that the two first baffle plates (101) are provided with second sliding grooves (501) along the length direction thereof, and the two ends of the second fixing rod (502) are respectively provided with second sliding blocks matched with the two second sliding grooves (501);

the first upper clamping part (400) and the second upper clamping part (500) respectively comprise a first electric push rod (402) and a third U-shaped supporting block (403) with a downward opening;

one electric push rod (402) is vertically and downwardly arranged on the first fixing rod (401), the other electric push rod (402) is vertically and downwardly arranged on the second fixing rod (502), and the output end of each first electric push rod (402) is provided with one third U-shaped supporting block (403).

5. The graphite anode special-shaped piece cutting device according to claim 4, characterized in that a plurality of lower fixing grooves (4031) are formed in each third U-shaped supporting block (403), a second fixing shaft is arranged in each lower fixing groove (4031), and a plurality of second ball bearings (4032) abutting against the outer surface of the graphite anode (1000) to be cut are sleeved on each second fixing shaft;

and a second vibration reduction layer is arranged on the peripheral wall of each second ball bearing (4032).

6. The graphite anode profile cutting device according to any one of claims 1 to 5, characterized in that the tip holder (600) comprises an L-shaped support plate (603), a first threaded rod (602), a second baffle (604) and a first drive motor (601);

the L-shaped supporting plate (603) is fixed on the side wall of the supporting table (100), a first threaded through hole is formed in the L-shaped supporting plate (603), a first threaded rod (602) penetrates through the first threaded through hole to be in threaded connection with the L-shaped supporting plate (603), a second baffle plate (604) is arranged at one end, close to the clamping assembly, of the first threaded rod (602), and the other end of the first threaded rod (602) is connected with an output shaft of a first driving motor (601) fixed on the side wall of the supporting table (100);

and a third vibration reduction layer is arranged on one surface of the second baffle (604) abutted against the graphite anode to be cut (1000).

7. The graphite anode profile cutting device according to claim 4, wherein each first baffle plate (101) is provided with a third sliding groove (701) along the length direction thereof, and the third sliding groove (701) is positioned above the second sliding groove (501);

the cutting assembly (700) comprises a sliding plate (702), a second electric push rod (703) and a cutting knife (704);

two sides of the sliding plate (702) correspond to the two third sliding grooves (701) one by one and are inserted into the third sliding grooves (701), a second electric push rod (703) is arranged at the bottom of the sliding plate (702), the output end of the second electric push rod (703) is connected with the cutting knife (704), and the second electric push rod (703) is used for driving the cutting knife (704) to move up and down relative to the graphite anode (1000) to be cut.

8. The graphite anode profile cutting device according to claim 2, 4 or 7, further comprising a drive assembly (800);

the driving assembly (800) comprises a fixing plate (802), a second threaded rod (803), a second driving motor (801), a third electric push rod (804) and a push plate (805);

the fixed plate (802) is relative end clamping part (600) sets up the other end of brace table (100), second screw thread through-hole has been seted up on fixed plate (802), second threaded rod (803) pass through second screw thread through-hole with fixed plate (802) threaded connection, the bottom of second threaded rod (803) with set up the output shaft of second driving motor (801) on brace table (100), the fixed third electric putter (804) that is provided with in top of second threaded rod (803), the output of third electric putter (804) is kept away from the top of second threaded rod (803) and is provided with push pedal (805).

9. The graphite anode profile cutting device according to claim 2, wherein the support table (100) is provided with a flow gathering hole (103) with a large upper part and a small lower part, the flow gathering hole (103) is located between the two first sliding grooves (102), the bottom of the flow gathering hole (103) is provided with a collection box (900) with an upper opening, the upper opening of the collection box (900) is opposite to the bottom of the flow gathering hole (103), and the diameter of the upper opening of the collection box (900) is larger than that of the lower opening of the flow gathering hole (103).

10. The graphite anode special-shaped piece cutting device according to claim 1, characterized in that a support column (104) is arranged on the lower surface of the support table (100), the top of the support column (104) is connected with the lower surface of the support table (100), and a pulley (1041) is arranged on the bottom of the support column (104).

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