CN221338978U - High-safety-coefficient full-automatic anode carbon block bottom grooving device for aluminum - Google Patents

Abstract

The utility model discloses a full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient, which comprises a base, a supporting rod, a top plate, a cutting wheel, a driving motor, an anode carbon block body and a hydraulic rod, wherein the supporting rod is fixedly arranged at the upper end of the base, the top plate is fixedly arranged at the upper end of the supporting rod, the cutting wheel is rotatably arranged at the middle end of the base, a fixed block is fixedly arranged at the upper end of the base, and a first rotating rod is arranged inside the fixed block in a penetrating manner. This positive pole carbon block bottom fluting device for aluminum automation that factor of safety is high, transport positive pole carbon block body to cutting wheel upper end through first conveyer belt, because hydraulic stem and rather than being synchronous motion this moment, then hydraulic stem pushes down positive pole carbon block and cuts, has realized improving the factor of safety of device, adopts automatic flow, protects staff's safety, reduces the injured probability of staff, has improved the availability and the efficiency of work of device.

Description

High-safety-coefficient full-automatic anode carbon block bottom grooving device for aluminum

Technical Field

The utility model relates to the technical field of anode carbon block slotting, in particular to a full-automatic aluminum anode carbon block bottom slotting device with high safety coefficient.

Background

The anode carbon block slotting device is a device which is needed in the processing and production process of anode carbon blocks, the bottoms of the anode carbon blocks are slotted, along with the continuous improvement of the social science and technology level, the material is needed in more and more aspects, but the existing anode carbon block bottom slotting device has the defect of a certain degree, for example:

The utility model discloses a pre-baked anode carbon block grooving device with the number of CN214871723U, which comprises a support frame and a chain conveyor, wherein the chain conveyor penetrates through the support frame, a saw blade is fixedly installed in the support frame and is arranged on a chain conveyor running line, a mounting plate is arranged at the top of the support frame, the upper end of the mounting plate is fixedly connected with a sliding rail, a sliding block is connected onto the sliding rail in a sliding manner, two groups of pneumatic telescopic rods are respectively and fixedly connected onto two sides of the sliding block, a sliding slot hole is formed in the mounting plate, the pneumatic telescopic rods are in sliding connection into the sliding slot hole, the lower end of each pneumatic telescopic rod is fixedly connected onto the upper end face of a pressing plate after penetrating through the sliding slot hole, a clamping block is fixedly connected onto one side edge of the pressing plate, and guiding devices are respectively and fixedly installed on two side edges of the mounting plate. The grooving device has the advantages of simple structure, high production quality, high working efficiency and anode slip prevention;

Foretell prebaked anode carbon block fluting device installs fixed guider respectively through mounting panel both sides edge and fixes the anode carbon block for the phenomenon of skidding is difficult for taking place when the anode carbon block in the course of the work, but when staff uses the device, need place the hand inside the device for add the anode carbon block that needs to carry out fluting, if staff takes place the incident easily carelessly, can't guarantee to staff's safety, simultaneously to the in-process that the anode carbon block was cut, not only offset about easily, also offset about can taking place, make the quality of final product unable assurance, the probability that leads to the defective product is great.

Disclosure of utility model

The utility model aims to provide a full-automatic anode carbon block bottom slotting device with high safety coefficient, which solves the problem that the safety accident is easy to occur if workers carelessly in the prior art, the safety of the workers cannot be ensured, the quality of a final product cannot be ensured, and the probability of occurrence of defective products is high.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the bottom grooving device for the full-automatic aluminum anode carbon block with the high safety coefficient comprises a base, a supporting rod, a top plate, a cutting wheel, a driving motor, an anode carbon block body and a hydraulic rod, wherein the supporting rod is fixedly arranged at the upper end of the base, the top plate is fixedly arranged at the upper end of the supporting rod, the cutting wheel is rotatably arranged at the middle end of the base, a fixed block is fixedly arranged at the upper end of the base, a first rotating rod is internally and penetratively arranged in the fixed block, the rear end of the first rotating rod is fixedly arranged at the output end of the driving motor, a first conveying belt is nested and arranged on the surface of the first conveying belt, the anode carbon block body is arranged at the upper end of the first conveying belt, a second conveying belt is nested and arranged on the surface of the second rotating rod, the front end and the rear end of the second rotating rod are rotatably arranged in the left side of the top plate, a first gear is penetratively arranged in the inner part of the top plate in a rotating manner, a lead screw is rotatably arranged at the inner part of the top plate, a left end of the reciprocating gear is fixedly arranged at the left end of the reciprocating screw rod, a movable platen is fixedly arranged at the lower end of the reciprocating screw rod, and the movable platen is fixedly arranged at the lower end of the reciprocating hydraulic rod;

The upper end surface of base has seted up the spout, and the inside nested of spout is installed and is walked the traveling wheel to the nested of traveling wheel is installed and is moved the movable plate, the inboard fixed mounting of movable plate has reset spring, and reset spring's inboard fixed mounting has splint.

Further, the front end and the rear end of the first rotating rod are installed between the front fixed block and the rear fixed block in a penetrating mode, the first rotating rod and the fixed blocks form a rotating structure through the driving motor, and the rotating structure shows the effect that the first rotating rod can rotate.

Further, the number of the first conveyor belts is two, namely front conveyor belts and rear conveyor belts, the first conveyor belts are hard, and the surface roughness of the first conveyor belts has large friction force, so that the structure reflects the number and the characteristics of the first conveyor belts.

Further, the first rotating rod forms a synchronous rotating structure with the second rotating rod through the second conveying belt, and the second rotating rod forms a rotating structure with the top plate through the second conveying belt, so that the effect that the first rotating rod drives the second rotating rod to rotate through the second conveying belt is reflected.

Further, the first gear is meshed with the second gear, the second gear and the reciprocating screw rod form a rotating structure through the first gear, and the structure shows the effect of meshed rotation of the first gear and the second gear.

Further, the connection mode of the reciprocating screw rod and the movable block is threaded connection, and the movable block forms a sliding structure with the top plate through the reciprocating screw rod, so that the effect that the reciprocating screw rod drives the movable block to move left and right is reflected.

Further, the splint form elastic structure through reset spring and movable plate, and movable plate and the connected mode of walking the wheel are rotated and are connected, and walk the connected mode of a wheel and spout and be sliding connection, and this structure has embodied movable plate and the effect that splint can the centre gripping.

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

1. the automatic slotting device for the bottom of the anode carbon block for aluminum with high safety coefficient is provided with a first conveyor belt which does not need a worker to stretch hands into the machine, the bottom of the anode carbon block body is automatically slotted, the anode carbon block body is transported to the upper end of a cutting wheel through the first conveyor belt, and at the moment, the hydraulic rod and the hydraulic rod synchronously move, so that the anode carbon block is pressed by the hydraulic rod to be cut, the safety coefficient of the device is improved, the safety of the worker is protected by adopting an automatic process, the possibility of injury of the worker is reduced, and the usability and the working efficiency of the device are improved;

2. This high full automatization of factor of safety is anode carbon block bottom fluting device is provided with the splint of stable centre gripping anode carbon block, carries out the centre gripping fixedly with the front and back both ends of anode carbon block through reset spring and splint, and the side-to-side slip through the movable plate simultaneously for it can follow the removal of anode carbon block and remove, and accurate stable carries out the centre gripping to anode carbon block and fixes, makes anode carbon block can keep stable in the fluting in-process, prevents because the fluting that rocks the lead to takes place the skew, makes product quality can guarantee, has reduced the waste of material.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model in a front cross-section;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 3 is a schematic side view of the present utility model;

FIG. 4 is a schematic view of a base of the present utility model in a top-down cross-sectional configuration;

FIG. 5 is an enlarged schematic view of the structure of FIG. 4B according to the present utility model;

Fig. 6 is a schematic diagram of a side cross-sectional structure of a moving plate according to the present utility model.

In the figure: 1. a base; 2. a support rod; 3. a top plate; 4. a cutting wheel; 5. a fixed block; 6. a first rotating lever; 7. a driving motor; 8. a first conveyor belt; 9. an anode carbon block body; 10. a second conveyor belt; 11. a second rotating lever; 12. a first gear; 13. a second gear; 14. a reciprocating screw rod; 15. a movable block; 16. a hydraulic rod; 17. an anti-slip pressure plate; 18. a chute; 19. a running wheel; 20. a moving plate; 21. a return spring; 22. and (3) clamping plates.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present utility model provides a technical solution: the utility model provides a high-safety-factor full-automatic anode carbon block bottom grooving device for aluminum, includes base 1, bracing piece 2, roof 3, cutting wheel 4, fixed block 5, first dwang 6, driving motor 7, first conveyer belt 8, anode carbon block body 9, second conveyer belt 10, second dwang 11, first gear 12, second gear 13, reciprocating screw 14, movable block 15, hydraulic rod 16, anti-skidding clamp plate 17, spout 18, running wheel 19, movable plate 20, reset spring 21 and splint 22.

In this embodiment: the upper end of the base 1 is fixedly provided with a supporting rod 2, the upper end of the supporting rod 2 is fixedly provided with a top plate 3, the middle end of the base 1 is rotatably provided with a cutting wheel 4, the upper end of the base 1 is fixedly provided with a fixed block 5, the inside of the fixed block 5 is penetrated and provided with a first rotating rod 6, the rear end of the first rotating rod 6 is fixedly provided with an output end of a driving motor 7, the surface of the first rotating rod 6 is nested and provided with a first conveyor belt 8, the upper end of the first conveyor belt 8 is provided with an anode carbon block body 9, the rear surface of the first rotating rod 6 is nested and provided with a second conveyor belt 10, the upper ends of the second conveyor belt 10 are nested and provided with a second rotating rod 11, the front end and the rear end of the second rotating rod 11 are rotatably provided with a first gear 12, the inside of the top plate 3 is rotatably provided with a reciprocating screw rod 14, the left end of the reciprocating screw rod 14 is fixedly provided with a second gear 13, the rear surface of the reciprocating screw rod 14 is nested and provided with a movable block 15, the lower end of the movable block 16 is fixedly provided with a hydraulic rod 16, and the lower end of the movable block 16 is fixedly provided with a hydraulic rod 17;

The upper end surface of the base 1 is provided with a chute 18, a traveling wheel 19 is nested inside the chute 18, a moving plate 20 is nested inside the traveling wheel 19, a return spring 21 is fixedly arranged on the inner side of the moving plate 20, and a clamping plate 22 is fixedly arranged on the inner side of the return spring 21.

The front end and the rear end of the first rotating rod 6 are installed between the front fixed block 5 and the rear fixed block 5 in a penetrating manner, the first rotating rod 6 and the fixed block 5 form a rotating structure through the driving motor 7, the number of the first conveyor belts 8 is two, the first conveyor belts 8 are hard, the surface roughness of the first conveyor belts 8 has larger friction force, the first rotating rod 6 and the second rotating rod 11 form a synchronous rotating structure through the second conveyor belts 10, the second rotating rod 11 and the top plate 3 form a rotating structure through the second conveyor belts 10, the first gear 12 and the second gear 13 are meshed with each other, the second gear 13 and the reciprocating screw 14 form a rotating structure through the first gear 12, the reciprocating screw 14 and the movable block 15 are connected in a threaded manner, and the movable block 15 and the top plate 3 form a sliding structure through the reciprocating screw 14;

According to fig. 1, fig. 2, fig. 3 and fig. 4, the slotting device for the bottom of the anode carbon block for the full-automatic aluminum with high safety coefficient starts a driving motor 7 when the device works, the driving motor 7 enables a first rotating rod to rotate 6, the first rotating rod 6 enables a first conveyor belt 8 to move when rotating, the first conveyor belt 8 rotates to drive an anode carbon block body 9 at the upper end to move together, the first rotating rod 6 rotates to drive a second rotating rod 11 to rotate through a second conveyor belt 10, the second rotating rod 11 rotates to enable a first gear 12 to rotate, the first gear 12 rotates to drive a second gear 13 to rotate, the second gear 13 rotates to drive a reciprocating screw 14 to rotate, the reciprocating screw 14 rotates to enable a movable block 15 to slide under the limit of a top plate 3, at the moment, because the reciprocating screw 14 and the first rotating rod 6 synchronously rotate, a hydraulic rod 16 at the lower end of the movable block 15 moves along with the anode carbon block body 9, and simultaneously an anti-skid pressing plate 17 at the lower end of the hydraulic rod 16 downwards pressurizes the anode carbon block body 9, so that the anode carbon block body 9 is fixed on the surface of the first conveyor belt 8, and the slotting device is cut safely and high-efficiency is realized;

The clamping plate 22 and the moving plate 20 form an elastic structure through the return spring 21, the moving plate 20 and the running wheel 19 are connected in a rotating way, and the running wheel 19 and the chute 18 are connected in a sliding way;

According to fig. 1, fig. 4, fig. 5 and fig. 6, this high-safety-factor full-automatic anode carbon block bottom grooving device for aluminum, before the cutting of anode carbon block body 9, through splint 22 and reset spring 21 with anode carbon block body 9 centre gripping, splint 22 at both ends make anode carbon block body 9 fixed around, because reset spring 21 outside movable plate 20, movable plate 20 bottom is provided with running wheel 19, running wheel 19 follows the removal of anode carbon block body 9 along spout 18 and moves, at this moment when anode carbon block body 9 cuts, anode carbon block body 9 is fixed around from top to bottom, match the frictional force on first conveyer belt 8 surface for its steady movement, vibrations when avoiding cutting lead to anode carbon block body 9 to taking place the skew.

What is not described in detail in this specification is prior art known to those skilled in the art.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an anode carbon block bottom fluting device for aluminum full automatization that factor of safety is high, includes base (1), bracing piece (2), roof (3), cutting wheel (4), driving motor (7), anode carbon block body (9) and hydraulic stem (16), its characterized in that: the upper end of the base (1) is fixedly provided with a supporting rod (2), the upper end of the supporting rod (2) is fixedly provided with a top plate (3), the middle end of the base (1) is rotatably provided with a cutting wheel (4), the upper end of the base (1) is fixedly provided with a fixed block (5), the inside of the fixed block (5) is penetrated and provided with a first rotating rod (6), the rear end of the first rotating rod (6) is fixedly provided with an output end of a driving motor (7), the surface of the first rotating rod (6) is nested and provided with a first conveying belt (8), the upper end of the first conveying belt (8) is provided with an anode carbon block body (9), the rear surface of the first rotating rod (6) is nested and provided with a second conveying belt (10), the upper end of the second conveying belt (10) is nested and is arranged on the surface of a second rotating rod (11), the front end and the rear end of the second rotating rod (11) are rotatably provided with a left side inside of the top plate (3), the rear end of the second rotating rod (11) is rotatably provided with a gear (12) which is fixedly provided with a first conveying belt (8), the upper end of the first rotating rod (14) is provided with a reciprocating screw rod (14), the lower end of the first rotating rod (14) is provided with a reciprocating screw rod (14), an anti-slip pressing plate (17) is fixedly arranged at the lower end of the hydraulic rod (16);

The sliding chute (18) is formed in the upper end surface of the base (1), the traveling wheels (19) are installed in the inner nest of the sliding chute (18), the moving plates (20) are installed in the nest of the traveling wheels (19), the reset springs (21) are fixedly installed on the inner sides of the moving plates (20), and clamping plates (22) are fixedly installed on the inner sides of the reset springs (21).

2. The full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient according to claim 1, wherein: the front end and the rear end of the first rotating rod (6) are installed between the front fixed block and the rear fixed block (5) in a penetrating mode, and the first rotating rod (6) and the fixed block (5) form a rotating structure through a driving motor (7).

3. The full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient according to claim 1, wherein: the number of the first conveyor belts (8) is two, namely, the front conveyor belt and the rear conveyor belt, the first conveyor belts (8) are hard, and the surface roughness of the first conveyor belts (8) has large friction force.

4. The full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient according to claim 1, wherein: the first rotating rod (6) and the second rotating rod (11) form a synchronous rotating structure through the second conveying belt (10), and the second rotating rod (11) and the top plate (3) form a rotating structure through the second conveying belt (10).

5. The full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient according to claim 1, wherein: the first gear (12) is meshed with the second gear (13), and the second gear (13) and the reciprocating screw rod (14) form a rotating structure through the first gear (12).

6. The full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient according to claim 1, wherein: the connecting mode of the reciprocating screw rod (14) and the movable block (15) is threaded connection, and the movable block (15) and the top plate (3) form a sliding structure through the reciprocating screw rod (14).

7. The full-automatic aluminum anode carbon block bottom grooving device with high safety coefficient according to claim 1, wherein: the clamping plate (22) and the movable plate (20) form an elastic structure through the reset spring (21), the movable plate (20) and the running wheel (19) are connected in a rotating mode, and the running wheel (19) and the sliding groove (18) are connected in a sliding mode.