CN112264669A

CN112264669A - Multifunctional alloy cutting equipment

Info

Publication number: CN112264669A
Application number: CN202011118189.6A
Authority: CN
Inventors: 张佳; 张亮
Original assignee: Shaoyang Huarui Alloy Tools Co ltd
Current assignee: Shaoyang Huarui Alloy Tools Co ltd
Priority date: 2020-10-19
Filing date: 2020-10-19
Publication date: 2021-01-26

Abstract

The invention discloses multifunctional alloy cutting equipment which comprises a base, wherein a cutting structure and a material receiving structure are arranged on the base; the cutting structure includes: the device comprises a workbench, two first mounting seats, two first motors, two first screw rods, two first sliding blocks, a first support, two first screw rod modules, two first hydraulic cylinders, a support, a second motor, a cutting knife and a fixing part; the automatic alloy collecting device has the advantages that the material collecting structure is arranged, alloy does not need to be collected manually by personnel, the workload of operators is reduced, the fatigue of the personnel is reduced, the cutting structure is arranged, the operators do not need to manually press and fix the alloy in the cutting process, the distance between the operators and equipment is increased, and the safety coefficient is improved.

Description

Multifunctional alloy cutting equipment

Technical Field

The invention relates to the technical field of alloy processing equipment, in particular to multifunctional alloy cutting equipment.

Background

Mixing one metal with another metal or several metals or non-metals, melting, cooling and solidifying so as to obtain the invented solid product with metal property.

The existing alloy cutting equipment only has a cutting function and does not have a material receiving function, an operator needs to manually collect the alloy, the workload of the operator is large, the fatigue of the operator is accelerated, in addition, the operator needs to manually press and fix the alloy in the cutting process, the operator is in close contact with the equipment, the safety coefficient is low, and in view of the above, the scheme is generated by carrying out deep research aiming at the problems.

Disclosure of Invention

The invention aims to solve the problems, designs multifunctional alloy cutting equipment, and solves the problems that the existing alloy cutting equipment only has a cutting function and does not have a material receiving function, an operator needs to manually collect the alloy, the workload of the operator is large, the fatigue of the operator is accelerated, in addition, the operator needs to manually press and fix the alloy in the cutting process, the operator closely contacts the equipment, and the safety coefficient is low.

The technical scheme of the invention for realizing the aim is as follows: a multifunctional alloy cutting device comprises a base, wherein a cutting structure and a material receiving structure are arranged on the base;

the cutting structure includes: the device comprises a workbench, two first mounting seats, two first motors, two first screw rods, two first sliding blocks, a first support, two first screw rod modules, two first hydraulic cylinders, a support, a second motor, a cutting knife and a fixing part;

the workbench is arranged on the upper wall surface of the base, the first mounting seats are arranged on the side wall surface of the workbench, the first motors are arranged on the inner side wall surfaces of the first mounting seats, the first lead screws are inserted into the first lead screws, the inner side wall surfaces of the first mounting seats are two, one ends of the first lead screws are connected to the first motor driving ends, the first sliding blocks are sleeved on the first lead screws, the first supports are arranged on the two upper wall surfaces of the first sliding blocks, the first lead screw modules are arranged on the lower wall surface of the first support, the first hydraulic cylinders are arranged on the two lower wall surfaces of the first lead screw modules, the supports are arranged on the two telescopic ends of the first hydraulic cylinders, the second motors are arranged on the lower wall surface of the supports, and the cutting knife is arranged on the second motor driving ends.

Preferably, the fixing portion includes: the two pairs of second mounting seats, the two pairs of third motors, the two pairs of second screw rods, the two pairs of second sliding blocks, the two second supports, the plurality of second hydraulic cylinders and the two pressing plates;

two pairs the second mount pad is installed in workstation lateral wall face, and two pairs the second mount pad is located two first mount pad top, two pairs third motor is installed in two pairs the interior lateral wall face of second mount pad, two pairs second lead screw cartridge is in two pairs the interior lateral wall face of second mount pad, and two pairs second lead screw one end is connected in two pairs third motor drive end, two pairs the second slider suit is in two pairs on the second lead screw, second support mounting is in two pairs wall, two on the second slider a plurality of recess, a plurality of have been seted up to the wall on the second support second pneumatic cylinder install in a plurality of in the recess, two the clamp plate symmetry is installed in a plurality of the flexible end of second pneumatic cylinder.

Preferably, receive the material structure and include: the two third supports, the two second lead screw modules, the two third hydraulic cylinders, the two mounting plates and the plurality of vacuum chucks;

the two third supports are arranged on the upper wall surface of the base, the two second lead screw modules are arranged on the two lower wall surfaces of the third supports, the two third hydraulic cylinders are arranged on the two lower wall surfaces of the movable ends of the second lead screw modules, the two mounting plates are arranged on the two telescopic ends of the third hydraulic cylinders, and the vacuum chucks are arranged on the two lower wall surfaces of the mounting plates at equal intervals.

Preferably, two first supporting rods are inserted into the inner side wall surfaces of the two first mounting seats, and the two first supporting rods are inserted into the two first sliding blocks.

Preferably, two second supporting rods are inserted into the inner side wall surfaces of the two second mounting seats, and the two second supporting rods are inserted into the two second sliding blocks.

Preferably, the two second supports are L-shaped structures, and the two second supports are provided with first anti-slip stickers.

Preferably, two the clamp plate is L type structure, two the clamp plate lower wall all installs the second antiskid and pastes.

Preferably, the side wall surface of the first bracket is provided with two first sliding strips, the side wall surface of the workbench is provided with two first sliding grooves, and the two first sliding strips are movably arranged in the two first sliding grooves.

Preferably, four second sliding strips are arranged on the side wall surfaces of the two second supports, two second sliding grooves are formed in the side wall surface of the workbench, and the four second sliding strips are movably arranged in the two second sliding grooves.

Preferably, two the wall all is equipped with two slide rails under the third support, and wall all is equipped with the telescopic link under two slide rail removal ends, the flexible end of telescopic link is installed on the mounting panel wall.

The multifunctional alloy cutting equipment manufactured by the technical scheme is provided with the material receiving structure, so that the alloy is not required to be manually collected by personnel, the workload of the operators is reduced, the fatigue of the personnel is reduced, the cutting structure is arranged, the operators are not required to manually press and fix the alloy in the cutting process, the distance between the operators and the equipment is increased, and the safety coefficient is improved.

Drawings

Fig. 1 is a schematic structural view of a multifunctional alloy cutting device according to the present invention.

FIG. 2 is a schematic side view of the multifunctional alloy cutting device according to the present invention.

FIG. 3 is a schematic structural diagram of a multifunctional alloy cutting device according to the present invention in a front view.

Fig. 4 is a schematic top view of a second bracket of the multifunctional alloy cutting device according to the present invention.

FIG. 5 is a partially enlarged schematic structural diagram of the multifunctional alloy cutting device shown in FIG. 1 according to the present invention.

In the figure: 1. a base; 2. a work table; 3. a first mounting seat; 4. a first motor; 5. a first lead screw; 6. a first slider; 7. a first bracket; 8. a first lead screw module; 9. a first hydraulic cylinder; 10. a support; 11. a second motor; 12. a cutting knife; 13. a second mounting seat; 14. a third motor; 15. a second lead screw; 16. a second slider; 17. a second bracket; 18. a second hydraulic cylinder; 19. pressing a plate; 20. a third support; 21. a second lead screw module; 22. a third hydraulic cylinder; 23. mounting a plate; 24. a vacuum chuck; 25. a first support bar; 26. a second support bar; 27. a first anti-slip patch; 28. a second anti-slip patch; 29. a first slide bar; 30. a second slide bar; 31. a slide rail; 32. a telescopic rod.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings, which show in fig. 1-5 a multi-functional alloy cutting apparatus.

All the electrical components in the present application are connected with the power supply adapted to the electrical components through the wires, and an appropriate controller should be selected according to actual conditions to meet the control requirements, and specific connection and control sequences should be obtained.

Example (b):

a multifunctional alloy cutting device comprises a base 1, wherein a cutting structure and a material receiving structure are arranged on the base 1;

in a specific implementation, the cutting structure may preferably adopt the following structure, which includes: the cutting machine comprises a workbench 2, two first mounting seats 3, two first motors 4, two first screw rods 5, two first sliding blocks 6, a first support 7, two first screw rod modules 8, two first hydraulic cylinders 9, a support 10, a second motor 11, a cutting knife 12 and a fixing part; the workbench 2 is arranged on the upper wall surface of the base 1, the two first installation seats 3 are arranged on the side wall surfaces of the workbench 2, the two first motors 4 are arranged on the inner side wall surfaces of the two first installation seats 3, the two first lead screws 5 are inserted into the inner side wall surfaces of the two first installation seats 3, one ends of the two first lead screws 5 are connected to the driving ends of the two first motors 4, the two first slide blocks 6 are sleeved on the two first lead screws 5, the first support 7 is arranged on the upper wall surface of the two first slide blocks 6, the two first lead screw modules 8 are arranged on the lower wall surface of the first support 7, the two first hydraulic cylinders 9 are arranged on the lower wall surface of the two first lead screw modules 8, the support 10 is arranged at the telescopic ends of the two first hydraulic cylinders 9, the second motor 11 is arranged on the lower wall surface of the support 10.

In a specific implementation, the fixing portion may preferably adopt the following structure, which includes: two pairs of second mounting seats 13, two pairs of third motors 14, two pairs of second screw rods 15, two pairs of second sliding blocks 16, two second supports 17, a plurality of second hydraulic cylinders 18 and two pressing plates 19; two pairs of second installation seats 13 are installed on the side wall surface of the workbench 2, the two pairs of second installation seats 13 are located above the two first installation seats 3, two pairs of third motors 14 are installed on the inner side wall surface of the two pairs of second installation seats 13, two pairs of second lead screws 15 are inserted into the inner side wall surface of the two pairs of second installation seats 13, one ends of the two pairs of second lead screws 15 are connected to the driving ends of the two pairs of third motors 14, two pairs of second sliders 16 are sleeved on the two pairs of second lead screws 15, a second support 17 is installed on the upper wall surface of the two pairs of second sliders 16, a plurality of grooves are formed in the upper wall surface of the two second supports 17, a plurality of second hydraulic cylinders 18 are installed in the plurality of grooves, and two pressing plates 19 are symmetrically installed at the.

In the specific implementation process, the receiving structure can preferably adopt the following structure, which comprises: two third brackets 20, two second lead screw modules 21, two third hydraulic cylinders 22, two mounting plates 23 and a plurality of vacuum chucks 24; two third supports 20 are installed on the upper wall surface of the base 1, two second lead screw modules 21 are installed on the lower wall surfaces of the two third supports 20, two third hydraulic cylinders 22 are installed on the lower wall surfaces of the moving ends of the two second lead screw modules 21, two installation plates 23 are installed on the telescopic ends of the two third hydraulic cylinders 22, and a plurality of vacuum suction cups 24 are installed on the lower wall surfaces of the two installation plates 23 at equal intervals.

Wherein, it is required to be noted that: by controlling the rotation of the two pairs of third motors 14, the two pairs of second screw rods 15 are rotated, the two pairs of second sliders 16 are moved accordingly, the distance between the two second brackets 17 is adjusted to be matched with the size of the alloy, the alloy is placed on the two second brackets 17, the plurality of second hydraulic cylinders 18 are controlled to contract to drive the two pressing plates 19 to compress the alloy, then the two first motors 4 are controlled to rotate, the two first screw rods 5 are rotated, the two first sliders 6 are moved accordingly to adjust the position of the cutting knife 12, then the two first hydraulic cylinders 9 are controlled to extend, meanwhile, the second motor 11 is operated to drive the cutting knife 12 to rotate, the two first screw rod modules 8 are operated to drive the cutting knife 12 to move, the alloy is cut, after the cutting is finished, the second screw rod module 21 is operated to drive the third hydraulic cylinders 22 to move until the plurality of vacuum suction cups 24 correspond to the cut alloy, then the third hydraulic cylinder 22 extends, the vacuum suckers 24 work to suck the alloy, then the second hydraulic cylinder 18 extends to loosen the alloy, the alloy is clamped, then the second lead screw module 21 works to enable the alloy to leave the pressing plate 19, then the third hydraulic cylinder 22 contracts, the moving end of the second lead screw module 21 moves reversely, and material collection is completed.

Preferably, two first supporting rods 25 are inserted into the inner side wall surfaces of the two first mounting seats 3, and the two first supporting rods 25 are inserted into the two first sliding blocks 6 to protect the two first screw rods 5.

Preferably, two second supporting rods 26 are inserted into the inner side wall surfaces of the two second mounting seats 13, and the two second supporting rods 26 are inserted into the two second sliding blocks 16 to protect the two pairs of second screw rods 15.

Preferably, the two second brackets 17 are both L-shaped, and the first anti-slip sticker 27 is mounted on each of the two second brackets 17 for preventing slipping.

Preferably, both the pressing plates 19 are L-shaped, and the lower wall surfaces of both the pressing plates 19 are provided with second anti-slip patches 28 for preventing slipping.

Preferably, two first sliding strips 29 are arranged on the side wall surface of the first bracket 7, two first sliding grooves are formed on the side wall surface of the workbench 2, and the two first sliding strips 29 are movably mounted in the two first sliding grooves and used for supporting the first bracket 7.

Preferably, four second sliding bars 30 are disposed on side wall surfaces of the two second brackets 17, two second sliding grooves are disposed on side wall surfaces of the workbench 2, and the four second sliding bars 30 are movably mounted in the two second sliding grooves and are used for supporting the two second brackets 17.

Preferably, the lower wall surfaces of the two third brackets 20 are provided with two sliding rails 31, the lower wall surfaces of the moving ends of the two sliding rails 31 are provided with telescopic rods 32, and the telescopic ends of the telescopic rods 32 are mounted on the upper wall surface of the mounting plate 23 for keeping the mounting plate 23 stable.

The technical solutions described above only represent the preferred technical solutions of the present invention, and some possible modifications to some parts of the technical solutions by those skilled in the art all represent the principles of the present invention, and fall within the protection scope of the present invention.

Claims

1. The multifunctional alloy cutting equipment comprises a base (1), and is characterized in that a cutting structure and a material receiving structure are arranged on the base (1);

the cutting structure includes: the cutting machine comprises a workbench (2), two first mounting seats (3), two first motors (4), two first screw rods (5), two first sliding blocks (6), a first support (7), two first screw rod modules (8), two first hydraulic cylinders (9), a support (10), a second motor (11), a cutting knife (12) and a fixing part;

the workbench (2) is arranged on the upper wall surface of the base (1), the two first installation seats (3) are arranged on the side wall surfaces of the workbench (2), the two first motors (4) are arranged on the inner side wall surfaces of the two first installation seats (3), the two first screw rods (5) are inserted into the inner side wall surfaces of the two first installation seats (3), one ends of the two first screw rods (5) are connected to the two driving ends of the first motors (4), the two first sliding blocks (6) are sleeved on the two first screw rods (5), the first support (7) is arranged on the upper wall surface of the two first sliding blocks (6), the two first screw rod modules (8) are arranged on the lower wall surface of the first support (7), the two first hydraulic cylinders (9) are arranged on the lower wall surface of the two first screw rod modules (8), and the support (10) is arranged at the telescopic ends of the two first hydraulic cylinders (9), the second motor (11) is installed on the lower wall surface of the support (10), and the cutting knife (12) is installed at the driving end of the second motor (11).

2. The multifunctional alloy cutting apparatus according to claim 1, wherein the fixing portion comprises: two pairs of second mounting seats (13), two pairs of third motors (14), two pairs of second screw rods (15), two pairs of second sliding blocks (16), two second supports (17), a plurality of second hydraulic cylinders (18) and two pressing plates (19);

two pairs of second mounting seats (13) are mounted on the side wall surfaces of the workbench (2), the two pairs of second mounting seats (13) are positioned above the two first mounting seats (3), two pairs of third motors (14) are mounted on the inner side wall surfaces of the two pairs of second mounting seats (13), two pairs of second screw rods (15) are inserted into the inner side wall surfaces of the two pairs of second mounting seats (13), one end of each pair of second screw rods (15) is connected with the driving ends of the two pairs of third motors (14), the two pairs of second sliding blocks (16) are sleeved on the two pairs of second screw rods (15), the second supports (17) are arranged on the upper wall surfaces of the two pairs of second sliding blocks (16), a plurality of grooves are formed in the upper wall surfaces of the two second supports (17), a plurality of second hydraulic cylinders (18) are arranged in the grooves, and the two pressing plates (19) are symmetrically arranged at the telescopic ends of the second hydraulic cylinders (18).

3. The multifunctional alloy cutting device as claimed in claim 1, wherein the material receiving structure comprises: the device comprises two third supports (20), two second lead screw modules (21), two third hydraulic cylinders (22), two mounting plates (23) and a plurality of vacuum suckers (24);

two third support (20) are installed on the wall on base (1), two second lead screw module (21) is installed in two wall under third support (20), two third pneumatic cylinder (22) are installed in two wall under second lead screw module (21) removal end, two mounting panel (23) are installed in two the flexible end of third pneumatic cylinder (22), a plurality of vacuum chuck (24) equidistance is installed in two wall under mounting panel (23).

4. The multifunctional alloy cutting equipment according to claim 1, characterized in that two first supporting rods (25) are inserted into the inner side wall surfaces of the two first installation seats (3), and the two first supporting rods (25) are inserted into the two first sliding blocks (6).

5. The multifunctional alloy cutting device according to claim 2, characterized in that two second supporting rods (26) are inserted into the inner side wall surfaces of the two second mounting seats (13), and the two second supporting rods (26) are inserted into the two second sliding blocks (16).

6. The multifunctional alloy cutting equipment according to claim 2, wherein the two second supports (17) are both L-shaped structures, and the first anti-slip paste (27) is mounted on each of the two second supports (17).

7. The multifunctional alloy cutting equipment as claimed in claim 2, characterized in that the two pressing plates (19) are both L-shaped structures, and the lower wall surfaces of the two pressing plates (19) are both provided with second anti-slip pastes (28).

8. The multifunctional alloy cutting equipment according to claim 1, wherein the side wall surface of the first bracket (7) is provided with two first sliding bars (29), the side wall surface of the workbench (2) is provided with two first sliding grooves, and the two first sliding bars (29) are movably arranged in the two first sliding grooves.

9. The multifunctional alloy cutting equipment according to claim 1, wherein four second sliding bars (30) are arranged on the side wall surfaces of the two second brackets (17), two second sliding grooves are formed in the side wall surface of the workbench (2), and the four second sliding bars (30) are movably arranged in the two second sliding grooves.

10. A multifunctional alloy cutting device according to claim 3, characterized in that two sliding rails (31) are arranged on the lower wall surfaces of the two third brackets (20), a telescopic rod (32) is arranged on the lower wall surfaces of the moving ends of the two sliding rails (31), and the telescopic end of the telescopic rod (32) is mounted on the upper wall surface of the mounting plate (23).