CN116765304A - Anti-vibration bracket forging equipment capable of continuously processing - Google Patents

Abstract

The application discloses vibration-resistant support forging equipment capable of continuously processing, and particularly relates to the field of machining equipment. The application has the advantages of simulating actions such as overturning and position adjustment when the machined part of the anti-vibration bracket is forged, so that the anti-vibration bracket is continuously processed and forged, thereby improving the processing efficiency, reducing the use of workers and carrying out automatic forging.

Description

Anti-vibration bracket forging equipment capable of continuously processing

Technical Field

The application relates to the technical field of machining equipment, in particular to vibration-resistant bracket forging equipment capable of continuously machining.

Background

As is well known, shock mounts are various types of components or devices that limit displacement of an accessory electromechanical engineering facility, control vibration of the facility, and transfer loads to a load bearing structure. The anti-seismic support gives reliable protection to the building electromechanical engineering facilities in the earthquake and bears the earthquake action from any horizontal direction; the anti-seismic bracket should be checked according to the load born by the anti-seismic bracket; all the components forming the anti-seismic bracket should be finished components, and the components connected with the fasteners should be convenient to install; the anti-seismic support of the heat-insulating pipeline is limited according to the design of the dimension of the heat-insulating pipeline, and the displacement generated by heat expansion and cold contraction of the pipeline is not limited, so that the use and the demand of the anti-seismic support are high. Forging equipment is typically used for efficient processing.

The application patent of patent application publication number CN109967681A discloses forging equipment, and the application sets up supporting mechanism through the below at forging mechanism, and supporting mechanism can support the product, simultaneously, utilizes the setting of arcwall face, push roll and support spacing roller, can carry out spacing to the product, like this in forging process, can receive spacing, can drive the product rotation through the rotation of push roll again, need not artifical manual rotation product in forging process like this, guarantees forging efficiency and quality, reduces operating personnel intensity of labour.

However, when the structure is actually used, the product can be limited to rotate, but the position of the top end of the product can be adjusted, and the side surface can not be turned over at the best, so that when the side surface of the product is forged, the manual adjustment is still needed, the whole processing is not continuous, and meanwhile, the forging efficiency is reduced, and therefore, the anti-vibration bracket forging equipment capable of continuously processing is provided.

Disclosure of Invention

In order to overcome the above-mentioned drawbacks of the prior art, the present application provides an anti-vibration bracket forging apparatus capable of continuous processing, so as to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides a vibration-resistant support forging equipment that can continuous processing, including the workstation, forge the platform, support and forging subassembly, install the forging platform on the workstation, the support has been erect in the forging bench outside, install forging subassembly on the support, push mechanism is installed to forging platform one side, push mechanism one side is connected with the organic case, install translation mechanism in the machine case, the hydraulic stem is installed to the support on the translation mechanism, the top box is installed to the hydraulic stem top, install slewing mechanism in the top box, install tilting mechanism on the slewing mechanism symmetry, fixture is installed to each tilting mechanism one end, through the synchronous operation of the second cylinder on two fixture, make two second push rods promote, make two clamping jaws close to each other, thereby the vibration-resistant support raw and other materials centre gripping, the hydraulic stem is elongated, make the raw and other materials be in suitable height, then, first cylinder operation makes first push rod promote the machine case, thereby make the machine case move on two slide rails, thereby make the machine case approach to the platform, make the raw and by the hydraulic stem cooperation, make the raw and other materials be in the bench, and forge forging subassembly, forging raw and other materials run by the hydraulic stem bottom end and forging subassembly are in succession;

after each forging, the first motor operates to enable the screw rod to rotate, so that the sliding block moves on the screw rod under the assistance of the guide rod, the raw material translates on the forging table, and the position of the raw material is adjusted;

after forging one end of the raw material, the two second rotating rods synchronously rotate through the synchronous operation of the two third motors, so that the mounting plate rotates along with the rotation of the mounting plate, the raw material clamped by the two clamping mechanisms is overturned, intermodulation is carried out at the upper end and the lower end, and the forging component is used for forging the other end of the raw material;

after the two ends of the raw material are forged, the raw material is overturned through the two turnover mechanisms, the raw material is parallel to the forging table, the hydraulic rod descends, the bottom of the raw material is connected with the forging table, then the forging component is forged, and when the position is replaced, the hydraulic rod operates through the second motor, the first rotary rod rotates, so that the connecting frame rotates, the raw material rotates, the forging position of the raw material is changed, then the raw material is loosened through the two clamping mechanisms, the raw material is connected with the forging table, the turnover mechanisms revolve again, the connecting frame is arranged, the raw material is clamped again through the two clamping mechanisms, the forging component operates again to forge, and the cycle is adopted, so that the circumference of the side surface of the raw material of the shock-resistant bracket can be forged, and continuous processing forging of the raw material of the shock-resistant bracket is formed.

Preferably, the pushing mechanism comprises a first cylinder mounted on the table.

And one end of the first push rod is connected with the first cylinder, and the other end of the first push rod is connected with the chassis.

And the two sliding rails are symmetrically arranged on the workbench and jointly support the bottom of the case.

Preferably, the translation mechanism includes a first motor mounted at one end inside the housing.

One end of the screw rod is connected with the first motor, and the other end of the screw rod is connected to the inner wall of the case.

And the two guide rods are symmetrically arranged at two sides of the screw rod, and two ends of the two guide rods are connected with the inner wall of the case.

The sliding block is sleeved on the screw rod, and two sides of the sliding block are respectively in sliding fit with the two guide rods.

Preferably, the rotating mechanism comprises a second motor, the second motor being mounted in the top box.

And one end of the first rotating rod is connected with the second motor.

The connecting frame is arranged at the other end of the first rotating rod.

Preferably, the tilting mechanism comprises a third motor, the third motor being mounted on the connecting frame.

And one end of the second rotating rod is connected with the third motor, and the other end of the second rotating rod is inserted into the connecting frame and protrudes out of the other side of the connecting frame.

The mounting plate is mounted at the other end of the second rotating rod.

Preferably, the clamping mechanism comprises a connecting plate bolted to the mounting plate.

And the second cylinder is arranged on the connecting plate.

And one end of the second push rod is connected with the second cylinder.

The clamping jaw is arranged at the other end of the second push rod.

Preferably, the bottom of the case is symmetrically provided with sliding grooves, and the two sliding rails are respectively inserted into the corresponding sliding grooves.

Preferably, a shaft disc is sleeved at one end of the screw rod and connected to the inner wall of the case.

Preferably, the top box is internally provided with a mounting groove, one side of the mounting groove is connected with a through groove, the second motor is arranged in the mounting groove, and the first rotating rod is inserted in the through groove.

Preferably, through holes are symmetrically formed in the connecting frame, shaft sleeves are arranged in the through holes, and the two second rotating rods are inserted into the corresponding shaft sleeves respectively.

The application has the technical effects and advantages that:

1. compared with the prior art, the position of the vibration-resistant bracket on the forging table where the raw materials of the vibration-resistant bracket are located can be adjusted through the arrangement of the first cylinder, the first push rod, the slide rail, the first motor, the screw rod, the guide rod and the slide block, so that the vibration-resistant bracket is convenient to forge, replaces manual operation, has high automation performance and improves the processing efficiency;

2. through second motor, first bull stick, the link, the third motor, the second bull stick, the mounting panel, the connecting plate, the second cylinder, second push rod and clamping jaw set up, compared with the prior art, not only can carry out the centre gripping to not unidimensional antidetonation support raw and other materials, moreover, can carry out automatic change forging and pressing end, and when can forge and press the raw and other materials side, automatically, adjust the forging and pressing face, thereby make the forging and pressing of antidetonation support raw and other materials more comprehensive, make the wholeness can be stronger, simultaneously, the manual work has been replaced completely and operated, make the whole automatic operation of equipment, machining forging efficiency has not only been improved, and manual use has been avoided, thereby reduce artifical use cost.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present application.

Fig. 2 is a schematic diagram of a connection structure of a pushing mechanism according to the present application.

Fig. 3 is a schematic structural view of the pushing mechanism of the present application.

Fig. 4 is a schematic structural view of the translation mechanism of the present application.

Fig. 5 is a schematic structural view of a rotating mechanism of the present application.

Fig. 6 is a schematic structural view of the turnover mechanism of the present application.

Fig. 7 is a schematic structural view of the clamping mechanism of the present application.

The reference numerals are: 1. a work table; 2. a forging stage; 3. a bracket; 4. forging and pressing the assembly; 5. a pushing mechanism; 501. a first cylinder; 502. a first push rod; 503. a slide rail; 6. a chassis; 7. a translation mechanism; 701. a first motor; 702. a screw rod; 703. a guide rod; 704. a slide block; 8. a hydraulic rod; 9. a top box; 10. a rotating mechanism; 1001. a second motor; 1002. a first rotating lever; 1003. a connecting frame; 11. a turnover mechanism; 1101. a third motor; 1102. a second rotating rod; 1103. a mounting plate; 12. a clamping mechanism; 1201. a connecting plate; 1202. a second cylinder; 1203. a second push rod; 1204. clamping jaw.

Detailed Description

The following description of the embodiments of the present application 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 application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

An anti-vibration bracket forging device capable of continuously processing as shown in the accompanying drawings 1-7 comprises a workbench 1, a forging platform 2, a bracket 3 and a forging component 4, wherein the forging platform 2 is installed on the workbench 1, the bracket 3 is connected to the outer side of the forging platform 2 in a framing manner, the forging component 4 is installed on the bracket 3, a pushing mechanism 5 is installed on one side of the forging platform 2, a case 6 is connected to one side of the pushing mechanism 5, a translation mechanism 7 is installed in the case 6, a hydraulic rod 8 is supported and installed on the translation mechanism 7, a top box 9 is installed on the top end of the hydraulic rod 8, a rotating mechanism 10 is installed in the top box 9, turning mechanisms 11 are symmetrically installed on the rotating mechanism 10, clamping mechanisms 12 are installed at one end of each turning mechanism 11, two second push rods 1203 are synchronously operated through second cylinders 1202 on the two clamping mechanisms 12 to push two clamping jaws 1204 to approach each other, thereby clamping the raw material of the vibration-resistant bracket, extending the hydraulic rod 8 to enable the raw material to be at a proper height, then, operating the first cylinder 501 to enable the first push rod 502 to push the case 6, enabling the case 6 to move on the two slide rails 503, enabling the case 6 to approach the forging table 2, enabling the raw material to be on the forging table 2, enabling the bottom end of the raw material to be connected with the forging table 2 under the cooperation of the hydraulic rod 8, operating the forging assembly 4 to forge the raw material, operating the first motor 701 after each forging, enabling the screw 702 to rotate, enabling the slider 704 to move on the screw 702 with the aid of the guide rod 703, enabling the raw material to translate on the forging table 2, adjusting the position of the raw material, after forging one end of the raw material, operating synchronously through the two third motors 1101, the two second rotating rods 1102 are synchronously rotated, so that the mounting plate 1103 rotates along with the rotation, raw materials clamped by the two clamping mechanisms 12 are turned over, the upper end and the lower end of the raw materials are intermodulation, the forging assembly 4 is used for forging and pressing the other end of the raw materials, after the two ends of the raw materials are forged and pressed, the raw materials are turned over by the two overturning mechanisms 11, the raw materials are parallel to the forging table 2, the hydraulic rod 8 descends, the bottom of the raw materials are connected with the forging table 2, the forging assembly 4 is forged and pressed, and then when the position is replaced, the second motor 1001 is used for operating the first rotating rod 1002, the connecting frame 1003 is rotated, the raw materials are rotated, the forging position of the raw materials is changed, the two clamping mechanisms 12 are then used for loosening the raw materials, the raw materials are connected with the forging table 2, the overturning mechanisms 11 are rotated again, the connecting frame 1003 is righted, the two clamping mechanisms 12 are used for clamping the raw materials again, the forging and pressing assembly 4 is used for forging and pressing again, and the circumference of the side surface of the raw materials of the anti-vibration bracket can be forged and pressed, and thus continuous vibration processing of the anti-vibration bracket is formed.

As shown in fig. 3, the pushing mechanism 5 includes a first cylinder 501, and the first cylinder 501 is mounted on the table 1.

The first push rod 502, one end of the first push rod 502 is connected with the first cylinder 501, and the other end is connected with the chassis 6.

Two slide rails 503, each slide rail 503 is symmetrically installed on the workbench 1, and supports the bottom of the chassis 6 together.

When the anti-vibration bracket raw material is placed on the forging stage 2, the first cylinder 501 operates so that the first push rod 502 pushes the case 6, so that the case 6 moves on the two slide rails 503, so that the case 6 approaches the forging stage 2, and the raw material is on the forging stage 2.

As shown in fig. 4, the translation mechanism 7 includes a first motor 701, and the first motor 701 is mounted at one end inside the cabinet 6.

The lead screw 702, lead screw 702 one end is connected with first motor 701, and the other end is connected on the inner wall of quick-witted case 6.

The two guide rods 703 are symmetrically arranged on two sides of the screw rod 702, and two ends of the two guide rods 703 are connected with the inner wall of the chassis 6.

The sliding block 704 is sleeved on the screw rod 702, and two sides of the sliding block 704 are respectively in sliding fit with the two guide rods 703.

When the position of the bottom end of the forging component 4 where the raw material of the vibration-resistant support is located is adjusted, the first motor 701 is operated to enable the screw rod 702 to rotate, so that the sliding block 704 moves on the screw rod 702 with the aid of the guide rod 703, the raw material is translated on the forging table 2, and the position of the raw material is adjusted.

As shown in fig. 5, the rotation mechanism 10 includes a second motor 1001, and the second motor 1001 is mounted in the top case 9.

And a first rotating rod 1002, wherein one end of the first rotating rod 1002 is connected with the second motor 1001.

A connection frame 1003, the connection frame 1003 is mounted at the other end of the first rotation lever 1002.

When the side forging position of the raw material of the shock-resistant bracket is changed in the continuous processing process, the second motor 1001 is operated, so that the first rotating rod 1002 rotates, the connecting frame 1003 rotates, the raw material rotates, the forging position of the raw material is changed, then the raw material is loosened by the two clamping mechanisms 12, the raw material is connected with the forging table 2, the turnover mechanism 11 rotates again, the connecting frame 1003 is aligned, the raw material is clamped again by the two clamping mechanisms 12, the forging assembly 4 operates again, and forging is performed, so that the circumference of the side surface of the raw material of the shock-resistant bracket can be forged, and continuous processing forging of the raw material of the shock-resistant bracket is formed.

As shown in fig. 6, the tilting mechanism 11 includes a third motor 1101, and the third motor 1101 is mounted on a connection frame 1003.

And one end of the second rotating rod 1102 is connected with the third motor 1101, and the other end of the second rotating rod 1102 is inserted into the connecting frame 1003 and protrudes out of the other side of the connecting frame 1003.

A mounting plate 1103, the mounting plate 1103 being mounted on the other end of the second rotating lever 1102.

When intermodulation forging is performed on two ends of the raw material of the vibration-resistant support, the two second rotating rods 1102 synchronously rotate through the synchronous operation of the two third motors 1101, so that the mounting plate 1103 rotates along with the rotation, the raw material clamped by the two clamping mechanisms 12 is overturned, intermodulation is performed on the upper end and the lower end, and the forging component 4 forges the other end of the raw material.

As shown in fig. 7, the clamping mechanism 12 includes a web 1201, the web 1201 being bolted to a mounting plate 1103.

A second cylinder 1202, the second cylinder 1202 being mounted on the connection plate 1201.

And one end of the second push rod 1203 is connected with the second cylinder 1202.

A clamping jaw 1204, the clamping jaw 1204 is arranged at the other end of the second push rod 1203.

When the vibration-resistant bracket raw material is clamped, the second air cylinders 1202 on the two clamping mechanisms 12 synchronously operate, so that the two second push rods 1203 are pushed, and the two clamping jaws 1204 are close to each other, so that the vibration-resistant bracket raw material is clamped.

As shown in fig. 3, the bottom of the chassis 6 is symmetrically provided with sliding grooves, and two sliding rails 503 are respectively inserted into the corresponding sliding grooves.

As shown in fig. 4, one end of the screw 702 is sleeved with a shaft disc, and the shaft disc is connected to the inner wall of the case 6.

As shown in fig. 5, a mounting groove is formed in the top case 9, a through groove is connected to one side of the mounting groove, the second motor 1001 is mounted in the mounting groove, and the first rotating rod 1002 is inserted in the through groove.

As shown in fig. 5, through holes are symmetrically formed on the connecting frame 1003, shaft sleeves are respectively installed in the through holes, and two second rotating rods 1102 are respectively inserted into the corresponding shaft sleeves.

The working principle of the application is as follows: when the vibration-resistant bracket forging equipment capable of continuous processing is utilized for forging vibration-resistant brackets, the second air cylinders 1202 on the two clamping mechanisms 12 synchronously operate, so that the two second push rods 1203 are pushed, the two clamping jaws 1204 are close to each other, raw materials of the vibration-resistant brackets are clamped, the hydraulic rod 8 is stretched, the raw materials are at a proper height, then the first air cylinders 501 operate, the first push rods 502 push the case 6, the case 6 moves on the two sliding rails 503, the case 6 is close to the forging table 2, the raw materials are on the forging table 2, the bottom ends of the raw materials are connected with the forging table 2 under the cooperation of the hydraulic rods 8, and the forging assembly 4 operates to forge the raw materials;

after each forging, the first motor 701 is operated to rotate the screw rod 702, so that the sliding block 704 moves on the screw rod 702 under the assistance of the guide rod 703, the raw material translates on the forging table 2, and the position of the raw material is adjusted;

after forging one end of the raw material, the two second rotating rods 1102 synchronously rotate through the synchronous operation of the two third motors 1101, so that the mounting plate 1103 rotates along with the rotation, the raw material clamped by the two clamping mechanisms 12 is overturned, intermodulation is performed at the upper end and the lower end, and the forging component 4 forges the other end of the raw material;

after the two ends of the raw material are forged, the raw material is turned over by the two turning mechanisms 11, the raw material is enabled to be parallel to the forging table 2, the hydraulic rod 8 descends, the bottom of the raw material is enabled to be connected with the forging table 2, then the forging component 4 is forged, and then when the position is replaced, the first turning rod 1002 is enabled to rotate by the second motor 1001, the connecting frame 1003 is enabled to rotate, the raw material is enabled to rotate, the forging position of the raw material is changed, then the two clamping mechanisms 12 loosen the raw material, the raw material is enabled to be connected with the forging table 2, the turning mechanisms 11 rotate again, the connecting frame 1003 is enabled to be righted, the two clamping mechanisms 12 clamp the raw material again, the forging component 4 runs again, and forging is enabled to circulate, so that the circumference of the side surface of the raw material of the shock-resistant bracket can be forged, and continuous processing forging of the raw material of the shock resistant bracket is formed.

The application has the advantages of simulating actions such as overturning and position adjustment when the machined part of the anti-vibration bracket is forged, so that the anti-vibration bracket is continuously processed and forged, thereby improving the processing efficiency, reducing the use of workers and carrying out automatic forging.

The last points to be described are: first, in the description of the present application, it should be noted that, unless otherwise specified and defined, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be mechanical or electrical, or may be a direct connection between two elements, and "upper," "lower," "left," "right," etc. are merely used to indicate relative positional relationships, which may be changed when the absolute position of the object being described is changed;

secondly: in the drawings of the disclosed embodiments, only the structures related to the embodiments of the present disclosure are referred to, and other structures can refer to the common design, so that the same embodiment and different embodiments of the present disclosure can be combined with each other under the condition of no conflict;

finally: the foregoing description of the preferred embodiments of the application is not intended to limit the application to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the application are intended to be included within the scope of the application.

Claims (10)

1. The utility model provides a antidetonation support forging equipment that can continuous processing, includes workstation (1), forges platform (2), support (3) and forging and pressing subassembly (4), install on workstation (1) and forge platform (2), outside frame has connect support (3) on forging platform (2), install forging and pressing subassembly (4), its characterized in that on support (3): push mechanism (5) are installed to forging platform (2) one side, push mechanism (5) one side is connected with organic case (6), install translation mechanism (7) in case (6), support on translation mechanism (7) and install hydraulic stem (8), top case (9) are installed on hydraulic stem (8) top, install slewing mechanism (10) in top case (9), tilting mechanism (11) are installed to symmetry on slewing mechanism (10), each tilting mechanism (11) one end is installed fixture (12).

2. The continuously workable anti-vibration stand forging apparatus of claim 1, wherein: the pushing mechanism (5) comprises a first air cylinder (501), and the first air cylinder (501) is arranged on the workbench (1);

one end of the first push rod (502) is connected with the first cylinder (501), and the other end of the first push rod (502) is connected with the chassis (6);

and the two sliding rails (503), wherein each sliding rail (503) is symmetrically arranged on the workbench (1) and supports the bottom of the chassis (6) together.

3. The vibration-resistant stand forging apparatus capable of continuous processing according to claim 2, wherein: the translation mechanism (7) comprises a first motor (701), and the first motor (701) is arranged at one end inside the case (6);

one end of the screw rod (702) is connected with the first motor (701), and the other end of the screw rod (702) is connected to the inner wall of the case (6);

the two guide rods (703), each guide rod (703) is symmetrically arranged at two sides of the screw rod (702), and two ends of the two guide rods (703) are connected with the inner wall of the chassis (6);

the sliding block (704), the sliding block (704) is sleeved on the screw rod (702), and two sides of the sliding block (704) are respectively in sliding fit with the two guide rods (703).

4. A continuously workable anti-vibration stand forging apparatus as claimed in claim 3, wherein: the rotating mechanism (10) comprises a second motor (1001), and the second motor (1001) is installed in the top box (9);

a first rotating rod (1002), wherein one end of the first rotating rod (1002) is connected with a second motor (1001);

and the connecting frame (1003) is arranged at the other end of the first rotating rod (1002).

5. The continuously workable anti-vibration stand forging apparatus of claim 4, wherein: the turnover mechanism (11) comprises a third motor (1101), and the third motor (1101) is installed on the connecting frame (1003);

one end of the second rotating rod (1102) is connected with the third motor (1101), and the other end of the second rotating rod (1102) is inserted into the connecting frame (1003) and protrudes out of the other side of the connecting frame (1003);

and the mounting plate (1103) is arranged at the other end of the second rotating rod (1102).

6. The continuously workable anti-vibration stand forging apparatus of claim 5, wherein: the clamping mechanism (12) comprises a connecting plate (1201), and the connecting plate (1201) is bolted to a mounting plate (1103);

a second cylinder (1202), the second cylinder (1202) being mounted on the connection plate (1201);

a second push rod (1203), wherein one end of the second push rod (1203) is connected with the second cylinder (1202);

and the clamping jaw (1204) is arranged at the other end of the second push rod (1203).

7. The continuously workable anti-vibration stand forging apparatus as recited in claim 6, wherein: the bottom of the case (6) is symmetrically provided with sliding grooves, and two sliding rails (503) are respectively inserted into the corresponding sliding grooves.

8. The continuously workable anti-vibration stand forging apparatus as recited in claim 7, wherein: one end of the screw rod (702) is sleeved with a shaft disc, and the shaft disc is connected to the inner wall of the case (6).

9. The continuously workable anti-vibration stand forging apparatus of claim 8, wherein: the mounting groove is formed in the top box (9), one side of the mounting groove is connected with the through groove, the second motor (1001) is mounted in the mounting groove, and the first rotating rod (1002) is inserted in the through groove.

10. The continuously workable anti-vibration stand forging apparatus as recited in claim 9, wherein: through holes are symmetrically formed in the connecting frame (1003), shaft sleeves are arranged in the through holes, and two second rotating rods (1102) are respectively inserted into the corresponding shaft sleeves.