Vertical rotary table numerical control apparatus

By designing the rotary module and machining module of the vertical turntable CNC equipment, multi-angle and diverse machining was achieved, solving the problem that existing CNC equipment could not perform multi-range machining, and improving production efficiency and product quality.

CN224333944UActive Publication Date: 2026-06-09DONGGUAN FALA CNC EQUIP

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN FALA CNC EQUIP
Filing Date
2025-05-07
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

The rotary table mechanism on existing CNC equipment is not easy to adjust, which makes it impossible to process parts in multiple ranges, increases labor costs and reduces efficiency.

Method used

A vertical rotary table CNC machine was designed, including a rotary module, a machining module, a lifting transmission component, and a transverse transmission component. Through the coordinated operation of these components, multi-angle and diverse machining can be achieved, and the distance between the machining head and the rotary table can be precisely adjusted to meet the machining needs of workpieces with different shapes and thicknesses.

Benefits of technology

It improves processing flexibility and precision, enhances production efficiency and product quality, meets the needs of complex processing tasks, and reduces labor costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to numerical control equipment technical field, concretely is a vertical turntable numerical control equipment, including frame, processing platform, rotation module and processing module, rotation module is located in the processing platform, and processing module is located in the frame, and processing module faces rotation module processing, rotation module includes support subassembly, rotating component and rotary disc, processing module includes lifting transmission component, horizontal transmission component and processing head, and lifting transmission component drives processing head to adjust the interval with rotary disc, horizontal transmission component drives processing head to adjust the distance with rotary disc, through rotation module and processing module, the clear division of labor and the coordinated operation, through rotating component drive rotary disc flexible rotation, can realize multi -angle processing, greatly improved the flexibility and the diversity of processing, can satisfy the work piece processing of different shape and process requirement, through lifting transmission component and horizontal transmission component flexible adjustment processing head and the distance of rotary disc, adapt to a variety of complex processing task, the practicality is strong.
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Description

Technical Field

[0001] This utility model relates to the field of CNC equipment technology, specifically a vertical rotary table CNC equipment. Background Technology

[0002] CNC equipment processes data and sends various control signals to control the machine tool's movements, automatically machining parts according to the shape and size required by the drawings. Vertical CNC equipment effectively solves the problem of machining complex, precise, small-batch, and multi-variety parts. It is a flexible, high-efficiency automated machine tool, representing the development direction of modern machine tool control technology, and is a typical mechatronics product.

[0003] The rotary table mechanism on existing CNC equipment has the disadvantage of being difficult to adjust, which prevents the CNC equipment from processing parts in a wide range. This requires operators to constantly adjust the position of the parts to achieve the desired effect of multi-range processing, resulting in high labor costs, inconvenience, and reduced efficiency and effectiveness of the CNC equipment. Utility Model Content

[0004] To address the aforementioned problems, this utility model provides a vertical rotary table CNC machine, which solves the shortcomings of existing CNC machines where the rotary table mechanism is difficult to adjust. This prevents the CNC machine from performing multi-range processing on parts, requiring operators to constantly adjust the position of the parts to achieve the desired multi-range processing effect. This results in high labor costs, inconvenience, and reduced efficiency and effectiveness of the CNC machine.

[0005] The technical solution adopted by this utility model is as follows: a vertical rotary table CNC machine, including a frame, a processing table, a rotary module, and a processing module; the rotary module is set on the processing table, the processing module is mounted on the frame, one end of the frame is vertically mounted on the processing table, and the processing module faces the rotary module for processing; the rotary module includes a support component, a rotating component, and a rotary disk, the support component is set on the processing table, the rotating component is movably mounted on the support component, and the rotary disk is mounted on the rotating component; one end of the rotating component drives the rotary disk to rotate on the support component; the processing module includes a lifting transmission component, a horizontal transmission component, and a processing head, one end of the lifting transmission component is mounted on the frame, the horizontal transmission component is mounted on the lifting transmission component, and the processing head is mounted on the rotating component; one end of the lifting transmission component drives the processing head to perform lifting transmission on the frame, for adjusting the distance between the processing head and the rotary disk; one end of the horizontal transmission component drives the processing head to perform linear transmission on the lifting transmission component, for adjusting the distance between the processing head and the rotary disk.

[0006] A further improvement to the above solution is that a control box is provided on the side of the frame near the processing module, and the control box is used to control the processing module and the rotating module.

[0007] A further improvement to the above solution is that a chip removal groove is provided on the processing table near the bottom of the rotating module, and the chip removal groove is a pull-out chip removal groove.

[0008] A further improvement to the above solution is that the support assembly includes a support platform and a support frame, and two sets of support frames are provided, which are arranged on both sides of the support platform. One end of the support frame is inclined towards the processing module.

[0009] A further improvement to the above solution is that the rotating assembly includes a rotating motor, a rotating reducer, a rotating bearing, a rotating bushing, and an assembly bushing. One end of the rotating motor is mounted on a support platform, the rotating reducer is mounted on the rotating motor, one end of the rotating bearing is connected to the rotating motor, one end of the rotating bushing is fitted onto the rotating bearing, and one end of the assembly bushing drives the rotating disk to be mounted on the rotating bushing.

[0010] A further improvement to the above solution is that the rotating disk includes an assembly disk and an assembly ring, the assembly ring is disposed on the assembly disk, the assembly disk is provided with an assembly groove, and one end of the rotating bearing passes through the assembly groove to drive the rotating disk to rotate.

[0011] A further improvement to the above solution is that the wall surface of the rotating disk is provided with a groove, one end of the groove is provided with a chip discharge port, and multiple grooves are provided, which are arranged in a ring around the rotating disk.

[0012] A further improvement to the above solution is that the lifting transmission assembly includes a lifting screw, a lifting motor, and a lifting seat. One side of the lifting motor is mounted on the frame, one end of the lifting screw is mounted on the lifting motor, and the lifting seat is movably mounted on the lifting screw. A lifting reducer is provided at one end of the lifting motor, and the other end of the lifting motor is connected to the lifting screw to drive the lifting seat to move up and down along the lifting screw. The lifting transmission assembly also includes auxiliary transmission rods, of which two sets are provided, and the two sets of auxiliary transmission rods are located on both sides of the lifting screw.

[0013] A further improvement to the above solution is that the transverse transmission assembly includes a linear transmission frame, a linear slide rail, a linear slider, a linear seat, and a linear motor; the linear transmission frame is mounted on the lifting seat, the linear slide rail is mounted on the linear transmission frame, the linear slider is movably mounted on the linear slide rail, the linear seat is mounted on the linear slider, and the linear motor is mounted on one side of the linear transmission frame; one end of the linear motor is connected to drive the linear slider to move the linear seat linearly along the linear slide rail.

[0014] A further improvement to the above solution is that the processing head includes a processing frame, a processing motor, a processing shaft, and a processing cutter head. The processing frame is mounted on the linear support, the processing motor is mounted on the processing frame, one end of the processing shaft is mounted on the processing motor, and the processing cutter head is mounted on the processing shaft. One end of the processing motor is connected to drive the processing shaft to rotate the processing cutter head for processing.

[0015] The beneficial effects of this utility model are:

[0016] Compared to existing CNC equipment, this invention features a rotary module and a machining module respectively mounted on the frame and machining table, with clear division of labor and collaborative operation. A support assembly is securely mounted on the machining table, providing reliable support for the rotary module and rotary disk. The rotary module drives the rotary disk to rotate flexibly, enabling multi-angle machining and greatly improving machining flexibility and versatility, meeting the machining requirements of workpieces with different shapes and processes. A lifting transmission assembly drives the machining head to move up and down on the frame, precisely adjusting the distance between the machining head and the rotary disk to ensure a suitable working distance for machining workpieces of varying thicknesses, thus improving machining accuracy. A transverse transmission assembly drives the machining head linearly along the lifting transmission assembly, further flexibly adjusting the distance between the machining head and the rotary disk, allowing for precise control of the machining position according to specific needs during processing. Adaptable to various complex machining tasks, this invention improves production efficiency and product quality, demonstrating strong practicality. Attached Figure Description

[0017] Figure 1 This is a perspective view of the vertical rotary table CNC equipment of this utility model;

[0018] Figure 2 This is a top view of the vertical rotary table CNC equipment of this utility model;

[0019] Figure 3 This is the front view of the vertical rotary table CNC equipment of this utility model;

[0020] Figure 4 for Figure 3 Sectional view at point AA;

[0021] Figure 5 for Figure 4 Enlarged view of point A in the middle.

[0022] Explanation of reference numerals in the attached diagram: Frame 10, Control box 11;

[0023] 20 machining table, 21 chip removal trough;

[0024] Rotary module 30, support assembly 31, support platform 311, support frame 312, rotating assembly 32, rotating motor 321, rotating reducer 322, rotating bearing 323, rotating bushing 324, assembly bushing 325, rotating disk 33, assembly disk 331, assembly ring 332, assembly groove 334, groove 335, chip discharge port 336;

[0025] The components include: machining module 40, lifting transmission assembly 41, lifting lead screw 411, lifting motor 412, lifting seat 413, auxiliary transmission rod 414, transverse transmission assembly 42, linear transmission frame 421, linear slide rail 422, linear slider 423, linear seat 424, linear motor 425, machining head 43, machining frame 431, machining motor 432, machining shaft 433, and machining cutter head 434. Detailed Implementation

[0026] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. Preferred embodiments of this utility model are shown in the drawings. However, this utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a more thorough and complete understanding of the disclosure of this utility model.

[0027] It should be noted that when a component is said to be "fixed to" another component, it can be directly attached to the other component or there may be an intervening component. When a component is said to be "connected to" another component, it can be directly connected to the other component or there may be an intervening component.

[0028] Unless otherwise defined, 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 invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

[0029] like Figure 1-5As shown in the embodiment of this utility model, a vertical rotary CNC machine includes a frame 10, a machining table 20, a rotary module 30, and a machining module 40. The rotary module 30 is disposed on the machining table 20, and the machining module 40 is mounted on the frame 10. One end of the frame 10 is vertically disposed on the machining table 20, and the machining module 40 processes towards the rotary module 30. The rotary module 30 includes a support assembly 31, a rotating assembly 32, and a rotary disk 33. The support assembly 31 is disposed on the machining table 20, the rotating assembly 32 is movably disposed on the support assembly 31, and the rotary disk 33 is disposed on the rotating assembly 32. One end of the rotating assembly 32 drives the rotary disk 33 to rotate... The machining module 40 rotates on the support assembly 31. It includes a lifting transmission assembly 41, a transverse transmission assembly 42, and a machining head 43. One end of the lifting transmission assembly 41 is mounted on the frame 10, the transverse transmission assembly 42 is mounted on the lifting transmission assembly 41, and the machining head 43 is mounted on the rotating assembly 32. One end of the lifting transmission assembly 41 drives the machining head 43 to move up and down on the frame 10, adjusting the distance between the machining head 43 and the rotating disk 33. One end of the transverse transmission assembly 42 drives the machining head 43 to move linearly on the lifting transmission assembly 41, adjusting the distance between the machining head 43 and the rotating disk 33. In this embodiment, the rotating module 30 and the processing module 40 are respectively mounted on the frame 10 and the processing table 20, with clear division of labor and collaborative operation. The support component 31 is stably mounted on the processing table 20, providing reliable support for the rotating component 32 and the rotary disk 33. The rotating component 32 drives the rotary disk 33 to rotate flexibly, enabling multi-angle processing, greatly improving the flexibility and versatility of processing, and meeting the processing requirements of workpieces with different shapes and processes. The lifting transmission component 41 drives the processing head 43 to move up and down on the frame 10, which can precisely adjust the distance between the processing head 43 and the rotary disk 33, ensuring that a suitable working distance is maintained when processing workpieces of different thicknesses, thus improving processing accuracy. The transverse transmission component 42 drives the processing head 43 to move linearly on the lifting transmission component 41, further flexibly adjusting the distance between the processing head 43 and the rotary disk 33, allowing for precise control of the processing position according to specific needs during processing. It adapts to a variety of complex processing tasks, improves production efficiency and product quality, and has strong practicality.

[0030] like Figure 1 As shown, a control box 11 is provided on the side of the frame 10 near the processing module 40. The control box 11 is used to control the processing module 40 and the rotating module 30. In this embodiment, by placing the control box 11 on the side of the frame 10 near the processing module 40, it greatly facilitates the operator's real-time control of the processing module 40.

[0031] A chip removal groove 21 is provided below the machining table 20 near the rotating module 30. The chip removal groove 21 is a pull-out chip removal groove 21. In this embodiment, the chip removal groove 21 is cleverly positioned below the rotating module 30, which can collect the chips falling from the machining table 20 during the processing in a timely manner, avoiding the accumulation of chips in key parts of the equipment and affecting normal operation. Moreover, the pull-out design greatly facilitates the cleaning work.

[0032] like Figures 3 to 4 As shown, the support assembly 31 includes a support platform 311 and a support frame 312. Two sets of support frames 312 are provided, positioned on both sides of the support platform 311. One end of each support frame 312 faces the processing module 40 and is angled. In this embodiment, the two sets of support frames 312 positioned on both sides of the support platform 311 provide stable support for the equipment from both sides, ensuring the stability of the processing module 40 during operation and reducing the impact of shaking and vibration on processing accuracy. The angled design of one end of the support frame 312 facing the processing module 40 helps guide any falling debris or other contaminants down the slope, preventing accumulation and affecting equipment operation. Furthermore, the angled design can buffer the impact force generated during processing to a certain extent, reducing damage to the support assembly 31 and the overall equipment, extending the equipment's service life, and optimizing the overall structural stability of the equipment.

[0033] The rotating assembly 32 includes a rotating motor 321, a rotating reducer 322, a rotating bearing 323, a rotating bushing 324, and an assembly bushing 325. One end of the rotating motor 321 is mounted on the support platform 311, the rotating reducer 322 is mounted on the rotating motor 321, one end of the rotating bearing 323 is connected to the rotating motor 321, one end of the rotating bushing 324 is sleeved on the rotating bearing 323, and one end of the assembly bushing 325 drives the rotating disk 33 to be mounted on the rotating bushing 324. In this embodiment, the rotating motor 321 provides the power source for the entire component, ensuring that the device can operate. The rotating reducer 322 can precisely adjust the speed, so that the rotating disk 33 rotates at a suitable speed to meet the precision requirements of different processing needs. The rotating bearing 323 can reduce friction during rotation, ensure the smoothness and stability of rotation, and extend the service life of the component. The rotating bushing 324 protects the rotating bearing 323 on the one hand, and provides stable support for the mounting bushing 325 on the other hand. The mounting bushing 325 drives the rotating disk 33 to be installed on the rotating bushing 324, realizing the stable circular motion of the rotating disk 33.

[0034] like Figure 5As shown, the rotating disk 33 includes an assembly disk 331 and an assembly ring 332. The assembly ring 332 is disposed on the assembly disk 331, and the assembly disk 331 is provided with an assembly groove 334. One end of the rotating bearing 323 passes through the assembly groove 334, driving the rotating disk 33 to rotate. In this embodiment, by disposing of the assembly ring 332 on the assembly disk 331, the stability and reliability of the overall structure of the rotating disk 33 are enhanced, ensuring its integrity during operation. Furthermore, the fact that one end of the rotating bearing 323 passes through the assembly groove 334 enables precise assembly and connection between the shaft and the rotating disk 33, and also provides stable support for the shaft to drive the rotating disk 33 to rotate. This allows the rotating disk 33 to rotate smoothly and steadily under the drive of the shaft, ensuring the accuracy and stability of various operations during equipment operation and reducing the probability of equipment failure.

[0035] The rotating disk 33 has grooves 335 on its wall surface, and a chip discharge port 336 is provided at one end of each groove 335. Multiple grooves 335 are arranged around the rotating disk 33. In this embodiment, the grooves 335 effectively collect the chips generated during processing, preventing chips from scattering randomly in the processing area, ensuring a clean processing environment, and reducing interference with processing accuracy. Furthermore, the chip discharge port 336 allows for timely discharge of chips, preventing chip accumulation in the grooves 335, thus avoiding excessive chips affecting the normal rotation of the rotating disk 33 and ensuring stable equipment operation.

[0036] The lifting transmission assembly 41 includes a lifting screw 411, a lifting motor 412, and a lifting seat 413. One side of the lifting motor 412 is mounted on the frame 10, one end of the lifting screw 411 is mounted on the lifting motor 412, and the lifting seat 413 is movably mounted on the lifting screw 411. A lifting reducer is provided at one end of the lifting motor 412, and the other end of the lifting motor 412 is connected to the lifting screw 411 to drive the lifting seat 413 to move up and down along the lifting screw 411. The lifting transmission assembly 41 also includes auxiliary transmission rods 414, of which two sets are provided, and the two sets of auxiliary transmission rods 414 are located on both sides of the lifting screw. In this embodiment, the precise lifting motion is achieved through the cooperation of the lifting motor 412, the lifting screw 411 and the lifting seat 413, which can meet the height adjustment needs of CNC equipment in different working scenarios. The lifting reducer can effectively reduce the motor speed and increase the torque. The auxiliary transmission rod 414 makes the lifting action more stable and powerful, ensuring the stability of the equipment operation. The structure is compact and reasonable, easy to operate and highly practical.

[0037] The transverse transmission assembly 42 includes a linear transmission frame 421, a linear slide rail 422, a linear slider 423, a linear seat 424, and a linear motor 425. The linear transmission frame 421 is mounted on the lifting seat 413, the linear slide rail 422 is mounted on the linear transmission frame 421, the linear slider 423 is movably mounted on the linear slide rail 422, the linear seat 424 is mounted on the linear slider 423, and the linear motor 425 is mounted on one side of the linear transmission frame 421. One end of the linear motor 425 is connected to drive the linear slider 423 along the linear slide rail 422, causing the linear seat 424 to move linearly. In this embodiment, by mounting the linear motor 425 on one side of the linear transmission frame 421 and connecting one end to drive the linear slider 423, the linear seat 424 moves linearly, effectively improving the equipment's working efficiency. The design is reasonable, and the components work together harmoniously. The arrangement of the linear slide rail 422 and the slider ensures that the linear seat 424 can move smoothly and accurately along a specific direction, improving the stability and positioning accuracy of the equipment.

[0038] The machining head 43 includes a machining frame 431, a machining motor 432, a machining shaft 433, and a machining cutter head 434. The machining frame 431 is mounted on the linear support 424, the machining motor 432 is mounted on the machining frame 431, one end of the machining shaft 433 is mounted on the machining motor 432, and the machining cutter head 434 is mounted on the machining shaft 433. One end of the machining motor 432 is connected to drive the machining shaft 433 to rotate the machining cutter head 434 for machining. In this embodiment, the machining frame 431 is mounted on the linear support 424, ensuring the stable installation and precise positioning of the machining head 43, allowing it to operate accurately on a predetermined track. The machining motor 432, mounted on the machining frame 431, provides power support for the entire machining process, and its stable operation ensures the continuity of machining. The machining shaft 433 connects the motor and the cutter head, efficiently transmitting power and driving the cutter head to rotate at high speed, enabling various precision machining tasks. It can be flexibly replaced according to different machining needs, greatly improving the applicability and machining diversity of the equipment.

[0039] A vertical rotary CNC machine includes a frame 10, a machining table 20, a rotary module 30, and a machining module 40. The rotary module 30 is mounted on the machining table 20, and the machining module 40 is mounted on the frame 10. One end of the frame 10 is vertically mounted on the machining table 20, and the machining module 40 processes towards the rotary module 30. The rotary module 30 includes a support assembly 31, a rotating assembly 32, and a rotary disk 33. The support assembly 31 is mounted on the machining table 20, the rotating assembly 32 is movably mounted on the support assembly 31, and the rotary disk 33 is mounted on the rotating assembly 32. One end of the rotating assembly 32 drives the rotary disk 33 on the support assembly 31. The machining module 40 includes a lifting transmission assembly 41, a transverse transmission assembly 42, and a machining head 43. One end of the lifting transmission assembly 41 is mounted on the frame 10, the transverse transmission assembly 42 is mounted on the lifting transmission assembly 41, and the machining head 43 is mounted on the rotating assembly 32. One end of the lifting transmission assembly 41 drives the machining head 43 to move up and down on the frame 10, thereby adjusting the distance between the machining head 43 and the rotating disk 33. One end of the transverse transmission assembly 42 drives the machining head 43 to move linearly on the lifting transmission assembly 41, thereby adjusting the distance between the machining head 43 and the rotating disk 33. In this embodiment, the rotating module 30 and the processing module 40 are respectively mounted on the frame 10 and the processing table 20, with clear division of labor and collaborative operation. The support component 31 is stably mounted on the processing table 20, providing reliable support for the rotating component 32 and the rotary disk 33. The rotating component 32 drives the rotary disk 33 to rotate flexibly, enabling multi-angle processing, greatly improving the flexibility and versatility of processing, and meeting the processing requirements of workpieces with different shapes and processes. The lifting transmission component 41 drives the processing head 43 to move up and down on the frame 10, which can precisely adjust the distance between the processing head 43 and the rotary disk 33, ensuring that a suitable working distance is maintained when processing workpieces of different thicknesses, thus improving processing accuracy. The transverse transmission component 42 drives the processing head 43 to move linearly on the lifting transmission component 41, further flexibly adjusting the distance between the processing head 43 and the rotary disk 33, allowing for precise control of the processing position according to specific needs during processing. It adapts to a variety of complex processing tasks, improves production efficiency and product quality, and has strong practicality.

[0040] The above embodiments only illustrate several implementation methods of this utility model, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.

Claims

1. A vertical rotary table CNC machine, characterized in that: It includes a frame, a processing table, a rotating module, and a processing module; the rotating module is mounted on the processing table, the processing module is mounted on the frame, one end of the frame is vertically mounted on the processing table, and the processing module processes towards the rotating module; The rotating module includes a support assembly, a rotating assembly, and a rotating disk. The support assembly is mounted on a processing table, the rotating assembly is movably mounted on the support assembly, and the rotating disk is mounted on the rotating assembly. One end of the rotating assembly drives the rotating disk to rotate on the support assembly. The processing module includes a lifting transmission assembly, a transverse transmission assembly, and a processing head. One end of the lifting transmission assembly is mounted on the frame, the transverse transmission assembly is mounted on the lifting transmission assembly, and the processing head is mounted on the rotating assembly. One end of the lifting transmission assembly drives the processing head to move up and down on the frame, thereby adjusting the distance between the processing head and the rotary table; one end of the transverse transmission assembly drives the processing head to move linearly on the lifting transmission assembly, thereby adjusting the distance between the processing head and the rotary table.

2. The vertical rotary table CNC equipment according to claim 1, characterized in that: A control box is provided on the side of the frame near the processing module. The control box is used to control the processing module and the rotating module.

3. The vertical rotary table CNC equipment according to claim 1, characterized in that: The processing table is provided with a chip removal groove below the rotating module, and the chip removal groove is a pull-out chip removal groove.

4. The vertical rotary table CNC equipment according to claim 1, characterized in that: The support assembly includes a support platform and a support frame. Two sets of support frames are provided, with the two sets of support frames located on both sides of the support platform. One end of the support frame is inclined towards the processing module.

5. The vertical rotary table CNC equipment according to claim 4, characterized in that: The rotating assembly includes a rotating motor, a rotating reducer, a rotating bearing, a rotating bushing, and an assembly bushing. One end of the rotating motor is mounted on a support platform, the rotating reducer is mounted on the rotating motor, one end of the rotating bearing is connected to the rotating motor, one end of the rotating bushing is fitted onto the rotating bearing, and one end of the assembly bushing drives the rotating disk to be mounted on the rotating bushing.

6. The vertical rotary table CNC equipment according to claim 5, characterized in that: The rotating disk includes an assembly disk and an assembly ring. The assembly ring is disposed on the assembly disk, and the assembly disk is provided with an assembly groove. One end of the rotating bearing passes through the assembly groove, driving the rotating disk to rotate.

7. The vertical rotary table CNC equipment according to claim 6, characterized in that: The rotating disk has grooves on its wall surface, and a chip discharge port is provided at one end of each groove. There are multiple grooves arranged in a ring around the rotating disk.

8. The vertical rotary table CNC equipment according to claim 1, characterized in that: The lifting transmission assembly includes a lifting screw, a lifting motor, and a lifting seat. One side of the lifting motor is mounted on the frame, one end of the lifting screw is mounted on the lifting motor, and the lifting seat is movably mounted on the lifting screw. A lifting reducer is provided at one end of the lifting motor, and the other end of the lifting motor is connected to the lifting screw to drive the lifting seat to move up and down along the lifting screw. The lifting transmission assembly also includes auxiliary transmission rods, of which two sets are provided, and the two sets of auxiliary transmission rods are located on both sides of the lifting screw.

9. The vertical rotary table CNC equipment according to claim 8, characterized in that: The transverse transmission assembly includes a linear transmission frame, a linear slide rail, a linear slider, a linear seat, and a linear motor. The linear transmission frame is mounted on the lifting seat, the linear slide rail is mounted on the linear transmission frame, the linear slider is movably mounted on the linear slide rail, the linear seat is mounted on the linear slider, and the linear motor is mounted on one side of the linear transmission frame. One end of the linear motor is connected to drive the linear slider to move the linear seat in a linear motion along the linear slide rail.

10. The vertical rotary table CNC equipment according to claim 9, characterized in that: The processing head includes a processing frame, a processing motor, a processing shaft, and a processing cutter. The processing frame is mounted on the linear support, the processing motor is mounted on the processing frame, one end of the processing shaft is mounted on the processing motor, and the processing cutter is mounted on the processing shaft. One end of the processing motor is connected to drive the processing shaft to rotate the processing cutter for processing.