CN220129177U - Cutting device of graphite anode - Google Patents

Abstract

The utility model relates to the technical field of graphite anode processing, in particular to a graphite anode cutting device which comprises a workbench, wherein two slotted holes are formed in the top of the workbench, a first fixing hole is formed in one side of each slotted hole, and a sliding groove is formed in the two sides of each slotted hole. The utility model has the advantages that: this graphite anode's cutting device starts two motors when needs remove graphite anode, the output shaft of motor rotates and drives the lead screw and rotate, two lead screws rotate and then make two sliders remove, two sliders remove and then drive the clamp splice and remove, the clamp splice removes and then makes graphite anode remove, then cut graphite anode, automatic movement has been realized, current cutting device has been solved and has generally need manual the position that removes graphite anode after once cutting to graphite anode, certain work burden has been increased for the manual work, and manual movement precision is influenced easily, make the inaccurate problem of cutting.

Description

Cutting device of graphite anode

Technical Field

The utility model relates to the technical field of graphite anode processing, in particular to a cutting device of a graphite anode.

Background

The graphite anode is a graphite plate, block or bar used as an anode of an electrolytic tank in the electrolytic industry, and is prepared by taking petroleum coke and asphalt coke as aggregates and coal asphalt as an adhesive through raw material calcination, crushing and grinding, batching, kneading, forming, roasting, dipping, graphitization and machining.

In this regard, the utility model provides a graphite anode cutting device which solves the problems.

Disclosure of Invention

The object of the present utility model is to solve at least one of the technical drawbacks.

Therefore, an object of the present utility model is to provide a graphite anode cutting device, which solves the problems mentioned in the background art and overcomes the shortcomings in the prior art.

In order to achieve the above object, an embodiment of an aspect of the present utility model provides a cutting device for a graphite anode, including a workbench, two slots are provided at the top of the workbench, one side of each of the two slots is provided with a first fixing hole, two sides of each of the two slots are provided with a sliding slot, two inner parts of the first fixing holes are respectively inserted with a screw rod, one side of the workbench is provided with two motors, one side of an output shaft of each of the two motors is respectively fixedly connected with one side of a corresponding screw rod, two outer surfaces of the screw rods are respectively connected with a sliding block in a threaded manner, two top parts of the sliding blocks are respectively fixedly connected with a fixing block, one side of each of the fixing blocks is fixedly connected with a first electric push rod, one side of each of the two first electric push rods is fixedly connected with a clamping block, the top part of the workbench is fixedly connected with a supporting frame, the top part of the supporting frame is provided with a second fixing hole, the top part of the supporting frame is fixedly connected with a second electric push rod, and the outer surface of the second electric push rod is fixedly connected with a cutting knife at one side of the second electric push rod.

By adopting the technical scheme, the automatic cutting device has the function of automatic movement, the problem that the existing cutting device usually needs to manually move the position of the graphite anode after cutting the graphite anode once, the cutting precision is easily influenced, and the problem of inaccurate cutting is solved.

By any of the above schemes, preferably, the bottom of the workbench is fixedly connected with a plurality of support columns.

By any of the above schemes, preferably, the outer surfaces of the output shafts of the two motors are respectively inserted into the corresponding first fixing holes, and one sides of the two motors are fixedly connected with one side of the workbench.

By any of the above schemes, preferably, two sides of the two sliding blocks are fixedly connected with one plug-in block, and outer surfaces of the plurality of plug-in blocks are respectively plugged into the corresponding sliding grooves.

It is preferable in any of the above-described modes that the two clamping blocks are symmetrically arranged.

It is preferred from any of the above aspects that the cutter is located on top of two clamping blocks.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

this graphite anode's cutting device is at the during operation, place graphite anode between two clamp splice, start two first electric putter, two first electric putter's output shaft flexible drive clamp splice removes, and then when two clamp splice remove each other, press from both sides tight with graphite anode, then second electric putter, second electric putter's output shaft flexible drive cutting knife rises and descends, and then when the cutting knife descends, cut graphite anode, when need remove graphite anode, start two motors, the output shaft rotation of motor drives the lead screw and rotates, two lead screws rotate and then make two sliders remove, two sliders remove and then drive the clamp splice and remove, the clamp splice removes and then make graphite anode remove, then cut graphite anode, automatic movement has been realized, the current cutting device is in the position to graphite anode of cutting back usually need manual movement graphite anode, a certain work burden has been increased for the manual work, and manual movement precision receives the influence easily, make the inaccurate problem of cutting.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of an overall structure according to an embodiment of the present utility model;

FIG. 2 is a schematic side view of an embodiment of the present utility model;

fig. 3 is a schematic diagram of an explosive structure according to an embodiment of the present utility model.

In the figure: the cutting tool comprises a 1-workbench, a 101-slotted hole, a 102-supporting column, a 2-screw rod, a 3-motor, a 4-sliding block, a 5-first electric push rod, a 6-clamping block, a 7-supporting frame, an 8-second electric push rod and a 9-cutting knife.

Detailed Description

As shown in fig. 1 to 3, a graphite anode cutting device comprises a workbench 1, two slotted holes 101 are formed in the top of the workbench 1, a first fixing hole is formed in one side of each of the two slotted holes, a sliding groove is formed in two sides of each of the two slotted holes, a screw rod 2 is inserted into each of the two first fixing holes, two motors 3 are arranged on one side of the workbench 1, one sides of output shafts of the two motors 3 are fixedly connected with one side of the corresponding screw rod 2 respectively, a sliding block 4 is connected to the outer surfaces of the two screw rods 2 in a threaded manner, a fixing block is fixedly connected to the tops of the two sliding blocks 4, a first electric push rod 5 is fixedly connected to one side of each of the two fixing blocks, the two first electric push rods 5 are started, the output shafts of the two first electric push rods 5 stretch and draw a clamping block 6 to move, when the two clamping blocks 6 move mutually, the graphite anode is clamped, one side of each of the two first electric push rods 5 is fixedly connected with one clamping block 6, the top of the workbench 1 is fixedly connected with a supporting frame 7, the top of the supporting frame 7 is provided with a second fixing hole, the top of the supporting frame 7 is fixedly connected with a second electric push rod 8, then the second electric push rod 8, an output shaft of the second electric push rod 8 stretches and contracts to drive a cutting knife 9 to ascend and descend, when the cutting knife 9 descends, the graphite anode is cut, the outer surface of the output shaft of the second electric push rod 8 is inserted into the second fixing hole, one side of the output shaft of the second electric push rod 8 is fixedly provided with the cutting knife 9, the cutting knife 9 comprises a motor, a saw blade and a mounting shell (known technology), the motor drives the saw blade to rotate for cutting, the top of the mounting shell is fixedly mounted with one side of the output shaft of the second electric push rod 8.

A plurality of support columns 102 are fixedly connected to the bottom of the workbench 1.

The surface of the output shaft of two motors 3 is pegged graft respectively in the inside of corresponding first fixed orifices, one side of two motors 3 all with one side fixed connection of workstation 1, start two motors 3, the output shaft rotation of motor 3 drives lead screw 2 and rotates, two lead screws 2 rotate and then make two sliders 4 remove, two sliders 4 remove and then drive clamp splice 6 remove, clamp splice 6 remove and then make graphite positive pole remove, then cut graphite positive pole, realized automatic movement.

Two sides of two sliders 4 are fixedly connected with a plug block, the outer surfaces of a plurality of plug blocks are respectively plugged into the corresponding sliding grooves, and the plug blocks move in the sliding grooves through the arranged plug blocks, so that the sliders 4 move more stably.

The two clamping blocks 6 are symmetrically arranged.

The cutting knife 9 is located on top of the two clamping blocks 6.

A cutting device of graphite anode has the following working principle:

this graphite anode's cutting device is at the during operation, place graphite anode between two clamp splice 6, start two first electric putter 5, the flexible clamp splice 6 that drives of output shaft of two first electric putter 5 removes, and then when two clamp splice 6 remove each other, press from both sides tight with graphite anode, then second electric putter 8, the flexible cutting knife 9 that drives of output shaft of second electric putter 8 rises and descends, and then when cutting knife 9 descends, when need remove graphite anode, start two motors 3, motor 3's output shaft rotates and drives lead screw 2 and rotate, two lead screw 2 rotate and then make two sliders 4 remove, two sliders 4 remove and then drive clamp splice 6 remove, clamp splice 6 remove and then make graphite anode remove, then cut graphite anode, automatic movement has been realized.

Compared with the prior art, the utility model has the following beneficial effects compared with the prior art:

this graphite anode's cutting device is at the during operation, place graphite anode between two clamp splice 6, start two first electric putter 5, the flexible clamp splice 6 that drives of output shaft of two first electric putter 5 removes, and then when two clamp splice 6 remove each other, press from both sides tight with graphite anode, then second electric putter 8, the flexible cutting knife 9 that drives of output shaft of second electric putter 8 rises and descends, and then when cutting knife 9 descends, cut graphite anode, when need remove graphite anode, start two motors 3, motor 3's output shaft rotates and drives lead screw 2 and rotate, two lead screw 2 rotates and then make two sliders 4 remove, two sliders 4 remove and then drive clamp splice 6 remove, clamp splice 6 remove and then make graphite anode remove, then cut graphite anode, automatic movement has been realized, the position that needs manual work to remove graphite anode after cutting once to current cutting device, certain work burden has been increased for the manual work, and manual movement precision receives easily, make the inaccurate problem of cutting.

Claims (6)

1. A cutting device of graphite positive pole, its characterized in that: including workstation (1), two slotted holes (101) have been seted up at the top of workstation (1), two a first fixed orifices has all been seted up to one side of slotted holes (101), two a spout has all been seted up to the both sides of slotted holes (101), two the inside of first fixed orifices has all been pegged graft and has a lead screw (2), one side of workstation (1) is provided with two motor (3), two one side of the output shaft of motor (3) respectively with one side fixed connection of corresponding lead screw (2), two the equal threaded connection of surface of lead screw (2) has a slider (4), two the equal fixedly connected with in top of slider (4) a fixed block, two the equal fixedly connected with in one side of fixed block a first electric putter (5), two the equal fixedly connected with clamp splice (6) in one side of first electric putter (5), the top fixedly connected with support frame (7) of workstation (1), the top of support frame (7) has the output shaft of second electric putter (8), the output shaft of second electric putter (8) is fixed connection in the second fixed connection of second output shaft (8).

2. A graphite anode cutting device as claimed in claim 1, wherein: the bottom of the workbench (1) is fixedly connected with a plurality of support columns (102).

3. A graphite anode cutting device as claimed in claim 2, wherein: the outer surfaces of the output shafts of the two motors (3) are respectively inserted into the corresponding first fixing holes, and one sides of the two motors (3) are fixedly connected with one side of the workbench (1).

4. A graphite anode cutting device as claimed in claim 3, wherein: two sides of the two sliding blocks (4) are fixedly connected with one plug-in block, and the outer surfaces of the plug-in blocks are respectively plugged into the corresponding sliding grooves.

5. The graphite anode cutting device as claimed in claim 4, wherein: the two clamping blocks (6) are symmetrically arranged.

6. The graphite anode cutting device of claim 5, wherein: the cutting knife (9) is positioned at the top of the two clamping blocks (6).