CN220921530U

CN220921530U - Double-beam stable transmission machining center

Info

Publication number: CN220921530U
Application number: CN202322184156.7U
Authority: CN
Inventors: 李鑫; 龚鹏飞
Original assignee: Dongguan Fala Cnc Equipment Co ltd
Current assignee: Dongguan Fala Cnc Equipment Co ltd
Priority date: 2023-08-14
Filing date: 2023-08-14
Publication date: 2024-05-10
Anticipated expiration: 2033-08-14

Abstract

The utility model relates to the technical field of numerical control machining, in particular to a double-beam stable transmission machining center, which comprises a frame, a workbench and a supporting frame arranged around the periphery of the workbench; the X-axis transmission module is slidably arranged on the first cross beam and the second cross beam, the first cross beam is arranged on the Y-axis driving module, the driving motor is arranged on the first cross beam, the auxiliary guide rail is arranged on the second cross beam, the Y-axis driving module and the auxiliary guide rail are respectively connected to two sides of the Z-axis transmission bracket, and the Z-axis transmission bracket is movably arranged on the upright post; the Z axle drive module drive stand is along Z axle transmission support transmission, and the main shaft is connected with rotation drive module, and R axle drive module installation main shaft support promotes driven precision through double beam structure, and Y axle drive module drives Z axle transmission support and follows auxiliary guide rail transmission, drives rotation drive module seat rotation elevating movement, does benefit to processing drive module and operates at different position workstations, has promoted the precision of whole operation.

Description

Double-beam stable transmission machining center

Technical Field

The utility model relates to the technical field of numerical control machining, in particular to a machining center with double-beam stable transmission.

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, large batch processing is generally required, in the processing process, only independent cross beams are generally transmitted to a processing center, the practicality of the independent cross beams is low, the transportation is unstable, the transmission precision is inaccurate, so that the processing efficiency is low, and the existing wood pattern or hardware numerical control processing equipment can be improved.

Disclosure of utility model

In order to solve the problems, the utility model provides a double-beam stable transmission machining center which solves the problem that the transmission precision is inaccurate due to unstable transportation of the existing independent beams, adopts a double-beam structure, improves the transmission stability, and improves the machining precision, thereby having good application prospects.

The technical scheme adopted by the utility model is as follows: the double-beam stable transmission machining center comprises a frame, wherein the frame comprises a workbench and a support frame which is arranged around the periphery of the workbench;

The X-axis transmission modules are provided with two groups, and the two groups of X-axis transmission modules are respectively arranged on two sides of the support frame;

The Y-axis transmission module comprises a first beam, a second beam and a Y-axis driving module, wherein the first beam and the second beam are both slidably arranged on the X-axis transmission module, the Y-axis driving module is arranged on the first beam, a driving motor is arranged on the first beam, and an auxiliary guide rail is arranged on the second beam;

The Z-axis transmission module comprises a Z-axis transmission bracket, an upright post and a Z-axis driving module, wherein two sides of the Z-axis transmission bracket are respectively connected with the Y-axis driving module and the auxiliary guide rail, and the upright post can be movably arranged on the Z-axis transmission bracket; the Z-axis driving module is used for driving the upright post to move along the Z-axis transmission bracket;

The main shaft, the main shaft includes main shaft support, rotary drive module and R axle drive module, and processing drive module, rotary drive module installs on the stand, be connected with rotary drive module between the main shaft, R axle drive module installs on the main shaft support, processing drive module is connected with R axle drive module, processing drive module is towards the workstation, rotary drive module connects in the main shaft support, the main shaft is installed in the stand and is towards the workstation.

The technical scheme is further improved in that a control box is arranged on one side of the frame, an operation table is arranged on the control box, and the control box is used for controlling the electric connection of the X-axis transmission module, the Y-axis transmission module and the Z-axis transmission module.

In a further improvement of the scheme, chip grooves are formed in the periphery of the workbench and are used for discharging chips generated in the machining process.

The technical scheme is further improved in that the support frame is provided with a sliding door, the sliding door is provided with a sliding rail, and the sliding door slides on the sliding rail.

The X-axis transmission module comprises an X-axis base, an X-axis guide rail, an X-axis screw rod, an X-axis motor 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 scheme is further improved in that hollow structures are arranged inside the first cross beam and the second cross beam, and reinforcing columns are arranged on the hollow structures.

The further improvement to above-mentioned scheme does, the spliced pole is equipped with a plurality ofly, a plurality of the spliced pole all in the hollow out construction towards first crossbeam and second crossbeam continuous arrangement.

The technical scheme is further improved in that the Y-axis driving module comprises a Y-axis driving screw rod, and the Y-axis driving module drives the Y-axis driving screw rod to drive the Z-axis transmission support to slide along the auxiliary guide rail.

The improvement of the scheme is that an auxiliary cylinder is arranged on one side of the Z-axis transmission support and connected to the upright post, and the auxiliary cylinder is used for lifting the upright post.

The processing driving module is provided with an inserting port facing the workbench, and the inserting port is used for installing a cutter.

The utility model has the beneficial effects that:

The utility model improves the whole bearing capacity and the transmission precision through the double-beam structure of the Y-axis transmission module, so that the Y-axis transmission module drives the Z-axis transmission support to transmit, an auxiliary cylinder on the Z-axis transmission support is used for lifting the upright post, and the rotary driving module is arranged on the upright post, so that the rotary driving module is driven to perform lifting movement, the processing driving module is convenient to operate on work tables in different directions through rotary lifting, the working efficiency of the whole operation is further improved, the practicability and the processing precision are enhanced, and the utility model has good application prospect.

Drawings

FIG. 1 is a schematic perspective view of a double beam stable transmission machining center of the present utility model;

FIG. 2 is a schematic diagram of the Y-axis drive module, and spindle of FIG. 1;

FIG. 3 is a schematic view of the Y-axis drive module, and the spindle of FIG. 2 at another angle;

FIG. 4 is a schematic diagram of a Y-axis transmission module.

Reference numerals illustrate: the device comprises a frame 1, a workbench 11, a chip removal groove 111, a supporting frame 12, a sliding door 121, a control box 13 and an operating platform 14;

The X-axis transmission module 2, an X-axis base 21, an X-axis guide rail 22, an X-axis screw rod 23, an X-axis motor 24 and an X-axis transmission seat 25;

The Y-axis transmission module 3, a first beam 31, a driving motor 311, a second beam 32, an auxiliary guide rail 321, a Y-axis driving screw 33, a hollow structure 34 and a reinforcing column 35;

A Y-axis transmission module 4, a Z-axis transmission bracket 41, a stand column 42 and a Z-axis driving module 43;

Spindle 5, spindle holder 51, rotation driving module 52, R-axis driving module 53, and machining driving module 54.

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 4, in the embodiment of the present utility model, a double-beam stable transmission machining center includes a frame 1, where the frame 1 includes a workbench 11 and a support frame 12 surrounding the workbench 11; the X-axis transmission module 2 is provided with two groups, and the two groups of X-axis transmission modules 2 are respectively arranged on two sides of the support frame 12; the Y-axis transmission module 3 comprises a first cross beam 31, a second cross beam 32 and a Y-axis driving module, wherein the first cross beam 31 and the second cross beam 32 are both slidably arranged on the X-axis transmission module 2, the Y-axis driving module is arranged on the first cross beam 31, a driving motor 311 is arranged on the first cross beam 31, and an auxiliary guide rail 321 is arranged on the second cross beam 32; the Z-axis transmission module 4 comprises a Z-axis transmission bracket 41, an upright post 42 and a Z-axis driving module 43, wherein two sides of the Z-axis transmission bracket 41 are respectively connected with the Y-axis driving module and the auxiliary guide rail 321, and the upright post 42 can be movably arranged on the Z-axis transmission bracket 41; the Z-axis driving module 43 is used for driving the upright post 42 to move along the Z-axis transmission bracket 41; the main shaft 5 includes main shaft support 51, rotary driving module 52 and R axle drive module 53, processes the drive module 54, rotary driving module 52 installs on stand 42, be connected with rotary driving module 52 between the main shaft 5, R axle drive module 53 installs on main shaft support 51, processing drive module 54 is connected with R axle drive module 53, processing drive module 54 is towards workstation 11, rotary driving module 52 connects in main shaft support 51, main shaft 5 installs in stand 42 and towards workstation 11.

The frame 1 one side is equipped with control box 13, be equipped with operation panel 14 on the control box 13, control box 13 is used for controlling the electricity and connects, in this embodiment, is convenient for control X axle transmission module 2, Y axle transmission module 3 and the electricity of Z axle transmission module 4 are connected the processing through control box 13, control convenient operation promotes work efficiency and security performance.

The periphery of the working table 11 is provided with a chip removal groove 111, the chip removal groove 111 is used for discharging chips generated in the processing process, in the embodiment, the chip removal groove 111 can be used for guiding and discharging the chips generated in the processing process on the working table 11, the chips are prevented from being accumulated on the working table, and the working environment is ensured.

The support frame 12 is provided with the sliding door 121, the sliding door 121 is provided with a sliding rail, the sliding door 121 slides on the sliding rail, in this example, the sliding door 121 sliding along the track of the sliding rail is used for guiding and sliding the sliding door 121 while the stability of the sliding door 121 is enhanced, so that articles can conveniently enter the workbench 11 for operation through the sliding door 121, and the practicability is high.

The X-axis transmission module 2 comprises an X-axis base 21, an X-axis guide rail 22, an X-axis screw rod 23, an X-axis motor 24 and an X-axis transmission seat 25, wherein the X-axis motor 24 drives the X-axis screw rod 23 to drive the X-axis transmission seat 25 to transmit along the X-axis guide rail 22, in this embodiment, the X-axis motor 24 drives the X-axis screw rod 23 to drive the X-axis transmission seat 25 to transmit along the X-axis guide rail 22, so that the X-axis transmission module 2 can stably run, and the first beam 31 and the second beam 32 can be slidably mounted on the X-axis transmission module 2, and simultaneously drive the first beam 31 and the second beam 32 under the premise of stable running, so that the linkage performance and the practicability are improved.

The first crossbeam 31 and the second crossbeam 32 are both internally provided with a hollow structure 34, and the hollow structure 34 is provided with a reinforcing column 35, in this embodiment, the whole weight of the first crossbeam 31 and the second crossbeam 32 is reduced through the hollow reinforcing column 35, and the rigidity of the reinforcing column 35 is ensured under the action of the reinforcing column 35.

The reinforcing columns 35 are provided with a plurality of reinforcing columns 35, the reinforcing columns 35 are connected and distributed towards the first cross beam 31 and the second cross beam 32, in the embodiment, the reinforcing columns 35 are connected and distributed towards the first cross beam 31 and the second cross beam 32, the integral weight is lightened, the integral stability of the first cross beam 31 and the second cross beam 32 is guaranteed through the action of the reinforcing columns 35, and the structural reliability is improved.

The Y axle drive module includes Y axle drive lead screw 33, Y axle drive module drives Y axle drive lead screw 33 and drives Z axle transmission support 41 and slide along auxiliary guide rail 321, and in this embodiment, Y axle drive module includes Y axle motor and Y axle guide rail, through the effect of Y axle drive lead screw 33 and guide rail, drives the support at Y axle motor drive lead screw and slides along the guide rail, has strengthened the transmission stationarity that Y axle drive module drove Z axle transmission support 41, promotes transmission precision.

The Z axle drive module 43 one side is equipped with auxiliary cylinder, auxiliary cylinder connects in stand 42, auxiliary cylinder is used for picking up stand 42, in this embodiment, through auxiliary cylinder, further picks up stand 42, has promoted holistic operation precision.

The processing drive module 54 is equipped with interface 541 towards being equipped with in the workstation 11, interface 541 is used for pegging graft cutting element, in this embodiment, is used for pegging graft cutting element through interface 541 to make stand 42 carry out accurate cutting on workstation 11, and processing drive module 54 is connected in R axle drive module 53, has further promoted the practicality and the pluralism of processing drive module 54.

The machining center with the double-beam stable transmission comprises a frame 1, an X-axis transmission module 2, a Y-axis transmission module 3, a Z-axis transmission module 4 and a main shaft 5, wherein the frame 1 comprises a workbench 11 and a support frame 12 which is arranged around the periphery of the workbench 11; the X-axis transmission modules 2 are arranged on two sides of the support frame 12; the first beam 31 and the second beam 32 of the Y-axis transmission module 3 form a double-beam structure, the whole bearing capacity is improved, reinforcing columns 35 of hollow structures 34 are arranged in the double beams, the double beams are slidably arranged on the X-axis transmission module 2, the whole bearing capacity is ensured through the reinforcing columns 35, and the bearing capacity of the X-axis transmission module 2 is reduced through the hollow structures 34, so that the transmission precision is greatly improved; connect in Y axle drive module and auxiliary rail 321 through Z axle transmission support 41 to make Y axle drive module 3 drive Z axle transmission support 41 and carry out the transmission, but through stand 42 movable mounting on Z axle transmission support 41, and auxiliary cylinder is used for lifting up stand 42, rotary drive module 52 installs on stand 42 simultaneously, under the prerequisite that auxiliary cylinder drove stand 42 to do elevating movement, rotary drive module 52 has also been driven simultaneously and elevating movement is convenient for process drive module 54 and is operated on workstation 11 in different positions through rotatory elevation, further promoted the precision of overall operation, also strengthened holistic practicality and machining precision simultaneously, possess good application prospect.

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

1. The utility model provides a double-beam stable transmission's machining center which characterized in that: comprising

The rack comprises a workbench and a supporting frame which is arranged around the periphery of the workbench in a surrounding manner;

2. The dual beam stable transmission machining center of claim 1, wherein: the machine frame is characterized in that a control box is arranged on one side of the machine frame, an operation table is arranged on the control box, and the control box is used for controlling the electric connection of the X-axis transmission module, the Y-axis transmission module and the Z-axis transmission module.

3. The double beam stable transmission machining center of claim 2, wherein: the periphery of the workbench is provided with a chip removal groove, and the chip removal groove is used for discharging chips generated in the machining process.

4. A dual beam stable transmission machining center according to claim 3, wherein: the support frame is provided with a sliding door, the sliding door is provided with a sliding rail, and the sliding door slides on the sliding rail.

5. The dual beam stable transmission machining center of claim 1, wherein: the X-axis transmission module comprises an X-axis base, an X-axis guide rail, an X-axis screw rod, an X-axis motor 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.

6. The dual beam stable transmission machining center of claim 5, wherein: the first cross beam and the second cross beam are internally provided with hollow structures, and reinforcing columns are arranged on the hollow structures.

7. The dual beam stable transmission machining center of claim 6, wherein: the reinforcing columns are arranged in a plurality of mode and uniformly distributed in the hollow structure.

8. The dual beam stable transmission machining center of claim 7, wherein: the Y-axis driving module comprises a Y-axis driving screw rod, and the Y-axis driving module drives the Y-axis driving screw rod to drive the Z-axis transmission support to slide along the auxiliary guide rail.

9. The dual beam stable transmission machining center of claim 8, wherein: an auxiliary cylinder is arranged on one side of the Z-axis transmission support and connected to the upright post, and the auxiliary cylinder is used for lifting the upright post.

10. The dual beam stable transmission machining center of claim 1, wherein: the processing driving module is provided with an inserting port facing the workbench, and the inserting port is used for installing a cutter.