CN220480981U - Multi-station vacuum workbench machining center - Google Patents

Abstract

The utility model relates to the technical field of numerical control machining, in particular to a multi-station vacuum workbench machining center which comprises a frame, an X-axis transmission module, a Y-axis transmission module, a Z-axis transmission module and a machining driving module, wherein an X-axis transmission seat drives a workbench to slide along an X-axis screw rod, a multi-station structure is arranged on the workbench, various parts are machined through the multi-station structure, the practicability of the workbench is enhanced, the working efficiency is improved, a Y-axis transmission seat of the Y-axis transmission module drives a Z-axis transmission support to conduct linear transmission along a Y-axis guide rail, the Z-axis transmission support is provided with a Z-axis driving module to drive the Z-axis screw rod to conduct lifting transmission, and a machining driving module is arranged on the Z-axis transmission seat, so that the machining driving module can conduct linear transmission and lifting transmission simultaneously, the practicability of the machining driving module is enhanced, the machining driving module is improved, and the machining precision is improved, and the machining center has good application prospect.

Description

Multi-station vacuum workbench machining center

Technical Field

The utility model relates to the technical field of numerical control machining, in particular to a multi-station vacuum workbench machining center.

Background

The numerical control machining equipment is mechanical automation equipment for controlling the displacement of a machining tool and the displacement of a part to be machined by using digital information. The numerical control machining equipment generally comprises a workbench, an XYZ module, a machining spindle and other structures. The numerical control equipment can be used for hardware part machining, die machining, wood die machining and the like.

In the existing wood pattern or hardware processing equipment, a large amount of processing is generally required, only a single workbench is generally used for processing in the processing process, and the single workbench is used for processing, so that the working efficiency is low, and the existing wood pattern or hardware numerical control processing workbench equipment can be newly improved.

Disclosure of Invention

In order to solve the problems, the utility model provides a multi-station vacuum workbench machining center, which solves the problems that a workbench of the existing machining center does not have a multi-station vacuum workbench structure, adopts the multi-station structure, can process a plurality of parts, improves the working efficiency, and improves the precision of the transmission process of the machining center through a Y-axis transmission module, a Z-axis transmission module and an X-axis transmission module, so that the machining center improves the machining precision and has good application prospect.

The technical scheme adopted by the utility model is as follows: the multi-station vacuum workbench machining center comprises a frame, wherein the frame comprises a workbench and an adsorption groove arranged on the surface of the workbench, the adsorption groove is provided with a vacuum adsorption module, the vacuum adsorption module is connected with the adsorption groove, and the workbench is of a multi-station structure; x axle transmission module, X axle transmission module includes: the X-axis motor drives the X-axis screw rod to drive the X-axis transmission seat to transmit along the X-axis guide rail; the workbench is arranged on the X-axis transmission seat;

the Y-axis transmission module comprises a Y-axis base, a Y-axis guide rail, a Y-axis screw rod, a Y-axis motor and a Y-axis transmission seat, wherein the Y-axis motor drives the Y-axis screw rod to drive the Y-axis transmission seat to transmit along the Y-axis guide rail;

z axle transmission module, Z axle transmission module includes Z axle transmission support and locates Z axle drive module, Z axle lead screw, Z axle guide rail and Z axle transmission seat on the Z axle transmission support, on the Y axle transmission seat was located to Z axle transmission support, Z axle transmission seat is equipped with processing drive module, processing drive module is equipped with the cutter holder, the cutter holder is towards in the workstation, Z axle drive module drive Z axle lead screw drives Z and takes out the transmission seat and slide along Z axle guide rail lift.

The technical scheme is further improved in that the periphery of the workbench is provided with a coaming plate, and the coaming plate is used for sealing and surrounding the workbench.

The technical scheme is further improved in that the two sides of the coaming are provided with the portal frames, and the portal frames are provided with the control console.

The control console is used for controlling the electric connection of the X-axis transmission module, the Y-axis transmission module and the Z-axis transmission module.

The technical scheme is further improved in that the periphery of the workbench is provided with chip grooves, and the chip grooves are used for stacking waste materials on the workbench.

The improvement of the scheme is that the X-axis base is provided with a plurality of reinforcing columns, and the reinforcing columns are continuously arranged on the X-axis base.

A further development of the above-described solution provides that the auxiliary element is a cylinder.

In a further improvement of the scheme, auxiliary elements are arranged on two sides of the Z-axis transmission support and used for further lifting the Z-axis transmission seat.

The technical scheme is further improved in that the Z-axis screw rod is provided with a fixed block, and the fixed block is connected to the Z-axis transmission seat.

The technical scheme is further improved in that the Z-axis transmission seat is provided with a supporting plate, the supporting plate is provided with a positioning block, the positioning block is provided with a positioning element, and the processing driving module is arranged on the supporting plate.

The utility model has the beneficial effects that:

the existing workbench does not have a multi-station structure, the multi-station structure is arranged on the workbench, so that multiple parts can be synchronously machined, the working efficiency is improved, the adsorption groove is arranged on the workbench to adsorb machined parts, the adsorption machining stability of the parts is improved, the Y-axis transmission seat of the Y-axis transmission module drives the Z-axis transmission support to conduct linear transmission along the Y-axis guide rail, the Z-axis transmission support is provided with the Z-axis driving module to drive the Z-axis screw rod to drive the Z-axis transmission seat to conduct lifting transmission, and the Z-axis transmission seat is provided with the machining driving module, so that the machining driving module can conduct linear transmission and lifting transmission simultaneously, the practicability of the machining driving module and the machining precision of the machining driving module are improved, and the workbench has good application prospect.

Drawings

FIG. 1 is a schematic diagram of a three-dimensional structure of a machining center of a multi-station vacuum workbench of the utility model;

FIG. 2 is a front view of FIG. 1;

FIG. 3 is a cross-sectional view at A-A in FIG. 2;

FIG. 4 is a schematic diagram of a processing driving module;

fig. 5 is a schematic structural diagram of the Z-axis transmission module.

Reference numerals illustrate: the device comprises a frame 1, a workbench 11, a coaming 111, a portal frame 112, a console 113, a chip removal groove 114 and an adsorption groove 12;

the X-axis transmission module 2, an X-axis base 21, a reinforcing column 211, an X-axis motor 22, an X-axis screw rod 23, an X-axis guide rail 24 and an X-axis transmission seat 25;

the Y-axis transmission module 3, a Y-axis base 31, a Y-axis guide rail 32, a Y-axis screw 33, a Y-axis motor 34 and a Y-axis transmission seat 35;

the Z-axis transmission module 4, the Z-axis transmission bracket 41, the auxiliary element 411, the Z-axis driving module 42, the Z-axis screw 43, the fixed block 431, the Z-axis guide rail 44, the Z-axis transmission seat 45, the supporting plate 451, the positioning block 452 and the positioning element 453;

a processing driving module 5 and a tool holder 51.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. Preferred embodiments of the present utility model are shown in the drawings. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

As shown in fig. 1 to 5, in an embodiment of the present utility model, a multi-station vacuum table 11 machining center is characterized in that: the vacuum adsorption device comprises a frame 1, wherein the frame 1 comprises a workbench 11 and an adsorption groove 12 arranged on the surface of the workbench 11, the adsorption groove 12 is provided with a vacuum adsorption module, the vacuum adsorption module is connected with the adsorption groove 12, and the workbench 11 is of a multi-station structure;

the X-axis transmission module 2, the X-axis transmission module 2 includes: the X-axis motor 22 drives the X-axis screw rod 23 to drive the X-axis transmission seat 25 to transmit along the X-axis guide rail 24; the workbench 11 is arranged on the X-axis transmission seat 25; the Y-axis transmission module 3 comprises a Y-axis base 31, a Y-axis guide rail 32, a Y-axis screw rod 33, a Y-axis motor 34 and a Y-axis transmission seat 35, wherein the Y-axis motor 34 drives the Y-axis screw rod 33 to drive the Y-axis transmission seat 35 to transmit along the Y-axis guide rail 32;

the Z-axis transmission module 4, the Z-axis transmission module 4 includes Z-axis transmission support 41, and locates Z-axis drive module 42, Z-axis lead screw 43, Z-axis guide rail 44 and Z-axis transmission seat 45 on the Z-axis transmission support 41, the Z-axis transmission support 41 is located on the Y-axis transmission seat 35, Z-axis transmission seat 45 is equipped with the processing drive module 5, the processing drive module 5 is equipped with cutter holder 51, cutter holder 51 is in workstation 11, Z-axis drive module 42 drive Z-axis lead screw 43 drives Z and takes out the transmission seat and slide along Z-axis guide rail 44, in this embodiment, X-axis drive motor 22 and X-axis guide rail 24 of X-axis drive module 2 are all installed on X-axis base 31, X-axis lead screw 33 is connected to X-axis motor 34, and X-axis transmission seat 25 is installed on X-axis guide rail 24, Y-axis drive motor 34 and Y-axis guide rail 32 of Y-axis drive module 3 are all installed on Y-axis base 31, Y-axis lead screw 33 is connected to Y-axis motor 34, and Y-axis transmission seat 32 is installed on Y-axis guide rail 32.

As shown in fig. 1, the periphery of the workbench 11 is provided with a surrounding plate 111, and the surrounding plate 111 is used for sealing and surrounding the workbench 11, in this embodiment, the surrounding plate 111 is used for sealing and surrounding the workbench 11, so that chips and dust generated when the workbench 11 works are not easy to fly, and the discharge is uniformly treated.

The bounding wall 111 both sides are equipped with portal frame 112, be equipped with control cabinet 113 on the portal frame 112, in this embodiment, also mentioned supporting role to holistic machining center when further strengthening bounding wall 111 leakproofness through portal frame 112, the practicality is high, structural design is reasonable.

The console 113 is used for controlling the electrical connection of the X-axis transmission module 2, the Y-axis transmission module 3 and the Z-axis transmission module 4, and the electrical connection is uniformly controlled by the console 113 in the embodiment, so that the operation is convenient, and the working efficiency and the safety performance are improved.

The periphery of the workbench 11 is provided with a chip groove 114, the chip groove 114 is used for stacking waste materials on the workbench 11, in this embodiment, the waste materials are uniformly stacked through the chip groove 114, and the working efficiency and the working precision of the workbench 11 are improved.

The X-axis base 21 is provided with a plurality of reinforcing columns 211, a plurality of reinforcing ribs are continuously arranged on the X-axis base 21, and in this embodiment, stability of the overall transmission of the X-axis transmission module 2 driving the workbench 11 is improved through the continuously arranged reinforcing columns 211. And the hollow structure ensures that the weight of the workbench 11 is lightened under the original bearing force, so that the bearing force of the X-axis transmission seat 25 is lightened, and the stable operation performance of the X-axis transmission seat 25 driving the workbench 11 is ensured.

The auxiliary element is the cylinder, in this embodiment, through the cylinder, further lifts up Z axle drive seat, promotes the steadiness.

As shown in fig. 5, auxiliary elements 411 are disposed on two sides of the Z-axis transmission support 41, and the auxiliary elements 411 are used for further lifting the Z-axis transmission seat 45, in this embodiment, the auxiliary elements 411 are used for further lifting and driving the Z-axis transmission seat 45 along the Z-axis screw 43, so that the stable running performance of lifting and driving is further improved.

The fixed block 431 is arranged on the Z-axis screw 43, the fixed block 431 is connected to the Z-axis transmission seat 45, in this embodiment, the Z-axis transmission seat 45 is further fixed to the connection of the Z-axis screw and the fixed block through the fixed block 431, so that the connectivity of the Z-axis transmission in the transmission process is ensured, and the transmission precision and the stability are improved.

As shown in fig. 4, the support plate 451 is disposed on the Z-axis transmission seat 45, the support plate 451 is provided with a positioning block 452, a positioning element 453 is disposed on the positioning block 452, and the processing driving module 5 is disposed on the support plate 451.

The utility model discloses a machining center of a multi-station vacuum workbench 11, which comprises a frame 1, an X-axis transmission module 2, a Y-axis transmission module 3, a Z-axis transmission module 4 and a machining driving module 5, wherein an X-axis transmission seat 25 of the X-axis transmission module drives the workbench to slide along an X-axis screw rod 23, so that the transmission precision of the workbench 11 and the practicability of the workbench 11 are enhanced, the workbench 11 is provided with a multi-station structure, the surface of the multi-station structure is provided with an adsorption groove 12, multiple parts can be synchronously machined through the multi-station structure, multiple machining parts are adsorbed through the adsorption groove 12, the overall practicability of the workbench 11 and the machining precision are enhanced, the working efficiency is improved on the premise of keeping the machining precision, a Y-axis transmission seat 35 of the Y-axis transmission module 3 drives a Z-axis transmission support 41 to perform linear transmission along a Y-axis guide rail 32, the Z-axis transmission support 41 is provided with a Z-axis driving module 42 to drive a Z-axis transmission seat 45 to perform lifting transmission, and the Z-axis transmission seat 45 is provided with the machining driving module 5, so that the machining driving module 5 can simultaneously perform linear transmission and lifting transmission, and the multi-part machining precision is good in the application prospect of the machining driving module 5.

The foregoing examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (10)

1. A multistation vacuum table machining center, its characterized in that: the vacuum adsorption device comprises a frame, wherein the frame comprises a workbench and an adsorption groove arranged on the surface of the workbench, the adsorption groove is provided with a vacuum adsorption module, and the vacuum adsorption module is connected with the adsorption groove;

the X-axis transmission module comprises an X-axis base, an X-axis motor, an X-axis screw rod, an X-axis guide rail and an X-axis transmission seat, wherein the X-axis motor drives the X-axis screw rod to drive the X-axis transmission seat to transmit along the X-axis guide rail; the workbench is arranged on the X-axis transmission seat;

the Y-axis transmission module comprises a Y-axis base, a Y-axis guide rail, a Y-axis screw rod, a Y-axis motor and a Y-axis transmission seat, wherein the Y-axis motor drives the Y-axis screw rod to drive the Y-axis transmission seat to transmit along the Y-axis guide rail;

z axle transmission module, Z axle transmission module includes Z axle transmission support and locates Z axle drive module, Z axle lead screw, Z axle guide rail and Z axle transmission seat on the Z axle transmission support, on the Y axle transmission seat was located to Z axle transmission support, Z axle transmission seat is equipped with processing drive module, processing drive module is equipped with the cutter holder, the cutter holder is towards in the workstation, Z axle drive module drive Z axle lead screw drives Z and takes out the transmission seat and slide along Z axle guide rail lift.

2. The multi-station vacuum table machining center according to claim 1, wherein: the periphery of the workbench is provided with a coaming, and the coaming is used for sealing and surrounding the workbench.

3. The multi-station vacuum table machining center according to claim 2, wherein: the coaming both sides are equipped with the portal frame, be equipped with the control cabinet on the portal frame.

4. A multi-station vacuum table machining center according to claim 3, wherein: the control console is used for controlling the electric connection of the X-axis transmission module, the Y-axis transmission module and the Z-axis transmission module.

5. The multi-station vacuum table machining center according to claim 4, wherein: the periphery of the workbench is provided with a chip groove, and the chip groove is used for discharging waste materials on the workbench.

6. The multi-station vacuum table machining center according to claim 1, wherein: the X-axis base is provided with a plurality of reinforcing columns, and the reinforcing columns are continuously arranged on the X-axis base.

7. The multi-station vacuum table machining center according to claim 1, wherein: auxiliary elements are arranged on two sides of the Z-axis transmission support and used for further lifting the Z-axis transmission seat.

8. The multi-station vacuum table machining center according to claim 7, wherein: the auxiliary element is a cylinder.

9. The multi-station vacuum table machining center according to claim 1, wherein: the Z-axis screw rod is provided with a fixed block, and the fixed block is connected to the Z-axis transmission seat.

10. The multi-station vacuum table machining center according to claim 9, wherein: the Z-axis transmission seat is provided with a support plate, the support plate is provided with a positioning block, the positioning block is provided with a positioning element, and the processing driving module is arranged on the support plate.