CN216503852U

CN216503852U - Double-machine-table high-light machine machining center platform

Info

Publication number: CN216503852U
Application number: CN202122958338.6U
Authority: CN
Inventors: 黄慧
Original assignee: Younuo Intelligent Equipment Kunshan Co ltd
Current assignee: Younuo Intelligent Equipment Kunshan Co ltd
Priority date: 2021-11-29
Filing date: 2021-11-29
Publication date: 2022-05-13
Anticipated expiration: 2031-11-29

Abstract

The utility model is suitable for the technical field of double-machine-table high-speed machines, and provides a double-machine-table high-speed machine processing center platform which comprises a base, a support, a cutter assembly and a processing platform assembly, wherein the cutter assembly and the processing platform assembly are arranged in two groups, the processing platform assembly comprises a Y-axis driving mechanism, an X-axis driving mechanism and a processing table, a part to be processed is fixedly arranged on the processing table, the Y-axis driving mechanism and the X-axis driving mechanism are matched with each other to move the part to be processed to be under the cutter assembly, and a cutter in the cutter assembly processes and manufactures the part.

Description

Double-machine-table high-light machine machining center platform

Technical Field

The utility model relates to the technical field of double-machine-table high-light machines, in particular to a double-machine-table high-light-machine processing center platform.

Background

The double-worktable polisher is a mechanical device used for cutting a metal surface and capable of improving the smoothness and the light reflection degree of the metal surface, can achieve a mirror surface effect when a product is machined, and cutting knife lines cannot be seen, so that the double-worktable polisher is widely applied to a plurality of fine machining fields.

The existing double-machine high-light machine has limited functions, and the structure can only process one workpiece every time when in use, so that the production efficiency is low. The double-machine-table high-light machine is inconvenient to adjust the position and the angle of a processed article during processing, so that the processing quality is affected, the processed article is inconvenient to stably clamp and fix, and therefore a double-machine-table high-light machine processing center is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a double-machine-platform high-speed optical machine machining center platform and aims to solve the problems in the prior art.

In order to achieve the purpose, the utility model adopts the following technical scheme: a double-machine-table high-speed optical machine machining center platform comprises a base, a support, a cutter assembly and a machining platform assembly;

the base is horizontally arranged, the support is arranged on one side of the top surface of the base, and the support is fixedly connected with the base;

the middle position of the front side surface of the support is provided with the cutter components, the cutter components are arranged in two groups, the two groups of cutter components are arranged at opposite intervals, each cutter component comprises a lifting platform, a connecting block, a first motor, a cutter and a second motor, the lifting platform is positioned on the front side surface of the support, the lifting platform is of a hollow structure and is fixedly connected with the support, the second motor is arranged on the top surface of the lifting platform, the second motor is fixedly connected with the lifting platform, the output end of the second motor is connected with a threaded rod, the threaded rod is accommodated in the cavity of the lifting platform, the connecting block extends into the cavity of the lifting platform and is provided with a first threaded hole matched with the threaded rod, the threaded rod is movably connected with the connecting block, and the connecting block is positioned outside the cavity of the lifting platform and is provided with a through groove, the first motor is accommodated in the through groove, the first motor is fixedly connected with the connecting block, and the output end of the first motor is connected with the cutter;

the processing platform assembly is arranged in the middle of the top surface of the base and comprises two sets of processing platform assemblies, the two sets of processing platform assemblies are arranged at opposite intervals, the processing platform assemblies are located under the cutter assembly and comprise Y-axis driving mechanisms, X-axis driving mechanisms and processing tables, the Y-axis driving mechanisms are arranged on the top surface of the base, each Y-axis driving mechanism comprises a first U-shaped block, a first conveying groove and a first conveying belt, each first U-shaped block is fixedly connected with the base, each first conveying groove is formed in the top surface of each first U-shaped block, each first conveying belt is contained in each first conveying groove, each first conveying belt is slidably connected with each first conveying groove, each X-axis driving mechanism is arranged above each Y-axis driving mechanism, and each X-axis driving mechanism comprises a second U-shaped block, The bottom surface of the second U-shaped block is fixedly connected with the first conveyor belt, the top surface of the second U-shaped block is provided with the second conveyor groove, the second conveyor belt is contained in the second conveyor groove, the second conveyor belt is slidably connected with the second conveyor groove, the processing table is arranged above the X-axis driving mechanism, and the processing table is fixedly connected with the second conveyor belt.

Preferably, a hole is formed in the front side face of the lifting platform, and the connecting block penetrates through the hole to be connected with the threaded rod.

Preferably, the Y-axis driving mechanism further comprises four first limiting blocks, the first limiting blocks are arranged on the front end face and the rear end face of the first U-shaped block, and the first limiting blocks are fixedly connected with the first U-shaped block.

Preferably, the X-axis driving mechanism further comprises four second limiting blocks, the second limiting blocks are located at the tops of the front end face and the rear end face of the second U-shaped block, and the second limiting blocks are fixedly connected with the second U-shaped block.

Preferably, the top surface of the processing table is provided with a plurality of grooves, the grooves are arranged in parallel at intervals, the bottom wall of the groove is provided with a plurality of second threaded holes, and the plurality of second threaded holes are arranged at intervals along the bottom wall of the groove.

Preferably, the first conveyor belt and the second conveyor belt are respectively controlled by two servo motors, and output ends of the two servo motors are respectively connected with a transmission gear of the first conveyor belt and a transmission gear of the second conveyor belt.

The utility model has the advantages that:

1. the double-machine-table high-ray machine machining center platform has the characteristics of high machining precision, high workpiece machining quality and long service life of the machine tables, and the double-machine-table high-ray machine is provided with the two high-ray machine tables on the base, so that the high-ray machine can machine two workpieces simultaneously when working, each machine table is provided with a machining tool bit, the space is effectively saved, and two machines can be operated by one person;

2. the double-machine-table high-speed optical machine machining center platform is used as a machining center, so that the working efficiency of a high-speed optical machine can be effectively improved, the two machine tables cannot be interfered with each other, the machining precision of a machining main shaft can be effectively guaranteed, the machining quality of a workpiece is improved, the supporting table is not easy to wear, and the service life of the machine tables can be effectively prolonged;

3. when the cutter is replaced, only the cutter head needs to be detached, and the cutter head can be replaced, so that the cutter replacement is simple and convenient.

Drawings

FIG. 1 is a perspective view of the overall structure of the present invention;

FIG. 2 is a side cross-sectional view of the cutter assembly of the present invention;

FIG. 3 is a perspective view of the Y-axis drive mechanism of the present invention;

FIG. 4 is a top view of the Y-axis drive mechanism of the present invention;

FIG. 5 is a perspective view of the X-axis drive mechanism of the present invention;

FIG. 6 is a top view of the X-axis drive mechanism of the present invention;

FIG. 7 is a top view of a processing station configuration of the present invention;

in the figure: 1. a base; 2. a support; 3. a cutter assembly; 31. a lifting platform; 32. connecting blocks; 33. a first motor; 330. a through groove; 34. a cutter; 35. a second motor; 350. a threaded rod; 4. processing the platform assembly; 41. a Y-axis drive mechanism; 410. a first U-shaped block; 411. a first transfer slot; 412. a first conveyor belt; 413. a first stopper; 42. an X-axis drive mechanism; 420. a second U-shaped block; 421. a second transfer slot; 422. a second conveyor belt; 423. a second limiting block; 43. and a processing table.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Referring to fig. 1-7, the present invention provides a technical solution: a double-machine-table high-speed optical machine machining center platform comprises a base 1, a support 2, a cutter assembly 3 and a machining platform assembly 4.

The base 1 is horizontally arranged, one side of the top surface of the base 1 is provided with a support 2, and the support 2 is fixedly connected with the base 1;

the middle position of the front side surface of the support 2 is provided with two groups of cutter assemblies 3, the two groups of cutter assemblies 3 are arranged at intervals, each cutter assembly 3 comprises a lifting platform 31, a connecting block 32, a first motor 33, a cutter 34 and a second motor 35, the lifting platform 31 is positioned on the front side surface of the support 2, the lifting platform 31 is of a hollow structure, the lifting platform 31 is fixedly connected with the support 2, the second motor 35 is arranged on the top surface of the lifting platform 31, the second motor 35 is fixedly connected with the lifting platform 31, the output end of the second motor 35 is connected with a threaded rod 350, the threaded rod 350 is accommodated in the cavity of the lifting platform 31, the connecting block 32 extends into the cavity of the lifting platform 31 and is provided with a first threaded hole matched with the threaded rod 350, the threaded rod 350 is movably connected with the connecting block 32, the connecting block 32 is positioned outside the cavity of the lifting platform 31 and is also provided with a through groove 330, the first motor 33 is accommodated in the through groove 330, the first motor 33 is fixedly connected with the connecting block 32, and the output end of the first motor 33 is connected with the cutter 34;

the middle position of the top surface of the base 1 is provided with two groups of processing platform components 4, the two groups of processing platform components 4 are arranged at intervals, the processing platform components 4 are positioned under the cutter component 3, the processing platform components 4 comprise a Y-axis driving mechanism 41, an X-axis driving mechanism 42 and a processing table 43, the Y-axis driving mechanism 41 is arranged on the top surface of the base 1, the Y-axis driving mechanism 41 comprises a first U-shaped block 410, a first conveying groove 411 and a first conveying belt 412, the first U-shaped block 410 is fixedly connected with the base 1, the top surface of the first U-shaped block 410 is provided with the first conveying groove 411, the first conveying belt 412 is contained in the first conveying groove 411, the first conveying belt 412 is connected with the first conveying groove 411 in a sliding manner, the X-axis driving mechanism 42 is arranged above the Y-axis driving mechanism 41, the X-axis driving mechanism 42 comprises a second U-shaped block 420, a second conveying groove 421 and a second conveying belt 422, the bottom surface of the second U-shaped block 420 is fixedly connected with the first conveyor belt 412, the top surface of the second U-shaped block 420 is provided with a second conveyor groove 421, the second conveyor belt 422 is accommodated in the second conveyor groove 421, the second conveyor belt 422 is slidably connected with the second conveyor groove 421, the processing table 43 is arranged above the X-axis driving mechanism 42, and the processing table 43 is fixedly connected with the second conveyor belt 422.

In this embodiment, the second motor 35 in the cutter assembly 3 rotates to drive the threaded rod 350 to rotate, the threaded rod 350 rotates to drive the connecting block 32 to move up and down, the first motor 33 rotates to drive the cutter 34 to rotate to process the part, the first conveyor belt 412 and the second conveyor belt 422 on the Y-axis driving mechanism 41 and the X-axis driving mechanism 42 rotate to drive the first U-shaped block 410 to move in the Y-axis direction and the second U-shaped block 420 to move in the X-axis direction, and the processing can be performed everywhere on the plane of the part.

Furthermore, the front side of the lifting platform 31 is provided with a hole, and the connecting block 32 is connected with the threaded rod 350 through the hole.

In this embodiment, the hole is formed to facilitate the lifting movement of the connecting block 32. The elevating platform 31 is a hollow structure, which facilitates the installation of the threaded rod 350.

Further, the Y-axis driving mechanism 41 further includes four first limiting blocks 413, the first limiting blocks 413 are disposed on the front and rear end faces of the first U-shaped block 410, and the first limiting blocks 413 are fixedly connected to the first U-shaped block 410.

In this embodiment, the first stopper 413 is used to strictly control the movement of the second U-shaped block 420 on the top surface of the first U-shaped block 410, and prevent the second U-shaped block 420 from moving out of the range of the top surface of the first U-shaped block 410.

Further, the X-axis driving mechanism 42 further includes four second limiting blocks 423, the second limiting blocks 423 are located on the top of the front and rear end faces of the second U-shaped block 420, and the second limiting blocks 423 are fixedly connected to the second U-shaped block 420.

In this embodiment, the second stopper 423 functions to strictly control the movement of the processing table 43 on the top surface of the second U-shaped block 420, and to prevent the processing table 43 from moving out of the range of the top surface of the second U-shaped block 420.

Further, a plurality of grooves are formed in the top surface of the machining table 43 and are arranged in parallel at intervals, a plurality of second threaded holes are formed in the bottom wall of the groove, and the second threaded holes are arranged along the bottom wall of the groove at intervals.

In the present embodiment, the groove and the screw hole formed in the machining table 43 are members to be machined for fixing, and the machined part can be fixed to the machining table 43 with a bolt and a fixing piece.

Further, the first conveyor belt 412 and the second conveyor belt 422 are respectively controlled by two servo motors, and output ends of the two servo motors are respectively connected with a transmission gear of the first conveyor belt 412 and a transmission gear of the second conveyor belt 422.

In this embodiment, the rotation of the first conveyor belt 412 and the second conveyor belt 422 is driven by the rotation of the rotating gear on the crawler belt, and since the Y-axis driving mechanism 41 and the X-axis driving mechanism 42 move in the Y-axis direction and the X-axis direction, respectively, in order to avoid the mutual influence of the two driving mechanisms, two servo motors are provided, and the output ends of the two servo motors are respectively connected to the rotating gear on the first conveyor belt 412 and the rotating gear on the second conveyor belt 422, so that the two mechanisms can operate without interfering with each other.

The working principle and the using process of the utility model are as follows: after the machining device is installed, a part to be machined is fixedly installed on a machining table 43, the Y-axis driving mechanism 41 and the X-axis driving mechanism 42 are matched with each other to send the specific part of the part to be machined to be right below a cutter 34, the second motor 35 rotates to drive the threaded rod 350 to rotate, so that the connecting block 32 can move up and down, the connecting block 32 is lifted to the part to be machined, the first motor 33 rotates to drive the cutter 34 to rotate to machine the part, after machining is completed, the second motor 35 drives the connecting block 32 to reset, and the Y-axis driving mechanism 41 and the X-axis driving mechanism 42 are matched with each other to drive the part to reset to complete the whole machining.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. The utility model provides a duplex platform hi-lite machine machining center platform which characterized in that: comprises a base (1), a support (2), a cutter component (3) and a processing platform component (4);

the base (1) is horizontally arranged, the support (2) is arranged on one side of the top surface of the base (1), and the support (2) is fixedly connected with the base (1);

support (2) leading flank intermediate position sets up cutter unit (3), cutter unit (3) set up two sets ofly, two sets of cutter unit (3) relative interval sets up, cutter unit (3) include elevating platform (31), connecting block (32), first motor (33), cutter (34) and second motor (35), elevating platform (31) are located support (2) leading flank, elevating platform (31) are hollow structure, elevating platform (31) fixed connection support (2), second motor (35) set up elevating platform (31) top surface, second motor (35) with elevating platform (31) fixed connection, a threaded rod (350) is connected to second motor (35) output, threaded rod (350) hold in elevating platform (31) cavity, connecting block (32) stretch into elevating platform (31) cavity inside divide seted up one go up with threaded rod (350) on ) The threaded rod (350) is movably connected with the connecting block (32) through a matched threaded hole I, a through groove (330) is further formed in the connecting block (32) on the outer portion of the cavity of the lifting platform (31), the first motor (33) is contained in the through groove (330), the first motor (33) is fixedly connected with the connecting block (32), and the output end of the first motor (33) is connected with the cutter (34);

the machining platform assembly (4) is arranged in the middle of the top surface of the base (1), two sets of machining platform assemblies (4) are arranged, the two sets of machining platform assemblies (4) are arranged at intervals, the machining platform assemblies (4) are located under the cutter assembly (3), each machining platform assembly (4) comprises a Y-axis driving mechanism (41), an X-axis driving mechanism (42) and a machining table (43), each Y-axis driving mechanism (41) is arranged on the top surface of the base (1), each Y-axis driving mechanism (41) comprises a first U-shaped block (410), a first conveying groove (411) and a first conveying belt (412), each first U-shaped block (410) is fixedly connected with the base (1), each first conveying groove (411) is formed in the top surface of each first U-shaped block (410), each first conveying belt (412) is contained in each first conveying groove (411), first conveyer belt (412) with first conveyer trough (411) sliding connection, Y axle actuating mechanism (41) top sets up X axle actuating mechanism (42), X axle actuating mechanism (42) include second U type piece (420), second conveyer trough (421) and second conveyer belt (422), second U type piece (420) bottom surface with first conveyer belt (412) fixed connection, second U type piece (420) top surface has been seted up second conveyer trough (421), second conveyer belt (422) are held in second conveyer trough (421), second conveyer belt (422) with second conveyer trough (421) sliding connection, X axle actuating mechanism (42) top sets up processing platform (43), processing platform (43) with second conveyer belt (422) fixed connection.

2. The dual-machine-table high-speed optical machining center platform of claim 1, wherein: the front side surface of the lifting platform (31) is provided with a hole, and the connecting block (32) penetrates through the hole to be connected with the threaded rod (350).

3. The dual-machine-table high-speed optical machining center platform of claim 1, wherein: y axle actuating mechanism (41) still includes first stopper (413), first stopper (413) set up four, first stopper (413) are located on the terminal surface around first U type piece (410), first stopper (413) with first U type piece (410) fixed connection.

4. The dual-machine-table high-speed optical machining center platform of claim 1, wherein: the X-axis driving mechanism (42) further comprises four second limiting blocks (423), the second limiting blocks (423) are located at the tops of the front end face and the rear end face of the second U-shaped block (420), and the second limiting blocks (423) are fixedly connected with the second U-shaped block (420).

5. The dual-machine-table high-speed optical machining center platform of claim 1, wherein: the top surface of the processing table (43) is provided with a plurality of grooves which are arranged in parallel at intervals, the bottom wall of the groove is provided with a plurality of second threaded holes, and the plurality of second threaded holes are arranged along the bottom wall of the groove at intervals.

6. The dual-machine high optical mechanical processing center platform of claim 1, wherein: the first conveyor belt (412) and the second conveyor belt (422) are respectively controlled by two servo motors, and the output ends of the two servo motors are respectively connected with a transmission gear of the first conveyor belt (412) and a transmission gear of the second conveyor belt (422).