An automatic production line for machining parts

By combining conveyor motors and rotary motors in an automated production line, parts can be automatically conveyed and flipped, solving the problem of parts needing to be processed twice in existing technologies, thus improving processing efficiency and convenience.

CN224390499UActive Publication Date: 2026-06-23BAODING CHANGXIN MASCH MFG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BAODING CHANGXIN MASCH MFG CO LTD
Filing Date
2025-07-03
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing automated production lines typically process only one side of a part at a time, requiring the part to be transferred again for processing on the other side, resulting in a large workload and low efficiency.

Method used

Design an automated production line that uses a combination of conveyor motors, rotary motors, and clamping plates to achieve automatic conveying and flipping of parts, ensuring efficient processing on both sides.

Benefits of technology

It enables automated flipping and conveying of parts, reducing repetitive operations and improving processing efficiency and convenience.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224390499U_ABST
    Figure CN224390499U_ABST
Patent Text Reader

Abstract

The utility model relates to the production line field especially relates to a kind of automatic production line for part processing.Technical scheme: slidingly connected with moving slide on fixed slide rail, the front end part of moving slide is provided with longitudinal cylinder, the front end part of longitudinal cylinder is provided with connecting block, connecting block is provided with vertical cylinder, the lower end part of vertical cylinder is provided with sleeve column, the inside of sleeve column is provided with rotating motor, the lower end part transmission of rotating motor is connected with rotating ring frame, the side of rotating ring frame is provided with rotating motor, and rotating shaft is transmission connected on rotating motor.The utility model can be automatically displaced by setting moving slide on fixed slide rail, longitudinal cylinder and vertical cylinder telescopic can realize displacement adjustment work, sleeve column fixed rotating motor, rotating motor starts, drives rotating ring frame to rotate, realizes horizontal rotation adjustment, rotating motor starts, drives rotating shaft to rotate, realizes vertical rotation adjustment.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of production lines, and in particular to an automated production line for parts processing. Background Technology

[0002] A flexible automated production line is a production line that connects multiple adjustable machine tools (mostly specialized machine tools) and equips them with automated conveying devices. It relies on computer management and combines multiple production modes, thereby reducing production costs and making the best use of resources.

[0003] When existing parts are processed through automated production lines, most parts can only be processed on one side. After all parts on one side are processed, they need to be automatically transferred again to process the other side, resulting in a large workload and making processing difficult.

[0004] Therefore, since most existing automated production lines can only process one side of a part before processing the other side, resulting in a large workload, an automated production line for part processing can be designed to solve the above problems. Utility Model Content

[0005] To overcome the shortcomings of existing automated production lines, which can only process one side of a part during processing, and require automatic transfer to process the other side after all parts have been processed on one side, resulting in a large workload and difficulty in processing.

[0006] The technical solution of this utility model is as follows: an automated production line for parts processing, including a base plate and an automatic component. The rear end of the base plate is provided with the automatic component for automated production. The automatic component includes a fixed groove, with partitions between the fixed grooves. A conveyor motor is provided at the lower end of the front end of the fixed groove, and a conveyor shaft is drivenly connected to the conveyor motor. A track is closely attached to the outside of the conveyor shaft, and a rotating roller is provided on the conveyor shaft. A conveyor belt is provided outside the rotating roller. A fixed slide rail is provided at the rear end of the fixed groove, and a movable slide is slidably connected to the fixed slide rail. A longitudinal cylinder is provided at the front end of the movable slide, and a connecting block is provided at the front end of the longitudinal cylinder. A vertical cylinder is provided on the connecting block, and the lower end of the vertical cylinder... The system is equipped with a sleeve column, inside which is a rotary motor. The lower end of the rotary motor is connected to a rotary ring frame, and a rotary motor is located on one side of the rotary ring frame. A rotary shaft is connected to the rotary motor, and a bidirectional slide rail frame is mounted on the rotary shaft. A movable clamping plate is slidably connected to the bidirectional slide rail frame. When the conveyor motor is started, it drives the conveyor shaft and the rotating roller to rotate, thereby driving the conveyor belt to rotate automatically and realize the conveying work. Then, when the rotary motor is started, it drives the rotary ring frame to rotate, realizing the rotation in the horizontal direction. When the rotary motor is started, it drives the rotating shaft to rotate, realizing the rotation in the vertical direction. The movable clamping plate slides and clamps the parts on the bidirectional slide rail frame, and the clamped parts can then be flipped over.

[0007] Preferably, automatic components are used to automate the conveying and flipping processes.

[0008] Preferably, the fixing groove is set in the shape of an isosceles trapezoid, and a slot is provided in the middle.

[0009] Preferably, the conveyor motor, conveyor shaft, and rotating roller are arranged as one group and located at the lower end of the fixed groove, while the conveyor shaft and rotating roller are arranged as another group and located at the upper end of the fixed groove. The two groups are connected by a track coupling.

[0010] Preferably, the two sets are arranged on one side of the device, and there are two complete sets in total, which are arranged symmetrically.

[0011] Preferably, a base plate is provided at the front end of the fixing groove, and L-shaped frames are provided on both sides of the upper end of the base plate. Vertical push rods are provided on the L-shaped frames. The L-shaped frames and vertical push rods are set as a group, and there are two groups in total. The two groups are respectively set on both sides of the upper end of the base plate.

[0012] Preferably, a laser engraving tool is provided at the lower end of the vertical push rod on one side.

[0013] Preferably, the lower end of the vertical push rod on the other side is provided with a protective sleeve, inside which a grinding motor is installed. The lower end of the grinding motor is connected to a grinding shaft, and the lower end of the grinding shaft is provided with a grinding head.

[0014] The beneficial effects of this utility model are:

[0015] 1. By setting fixed slots and fixing partitions, the conveyor motor starts, driving the conveyor shaft and rotating rollers to rotate. The track is connected to the shaft, driving the conveyor belt to rotate, thus realizing automatic conveying. The movable carriage slides on the fixed slide rail, which can automatically adjust its displacement. The longitudinal cylinder is fixed to the connecting block, and the connecting block fixes the vertical cylinder. The extension and retraction of the longitudinal cylinder and the vertical cylinder can realize displacement adjustment. The sleeve column fixes the rotary motor. When the rotary motor starts, it drives the rotating ring to rotate, realizing lateral rotation adjustment. When the rotary motor starts, it drives the rotating shaft to rotate, realizing vertical rotation adjustment. The movable clamping plate slides on the bidirectional slide rail frame to fix and clamp the parts. Rotation can flip the parts for easy processing. This overcomes the shortcomings of existing automated production lines, which can mostly only process one side of the parts. After all the parts are processed on one side, they need to be automatically conveyed again to process the other side, resulting in a large workload and difficulty in processing.

[0016] 2. By setting a fixed groove to fix the partition, the conveyor motor starts, driving the conveyor shaft and rotating roller to rotate. The track is connected to the shaft, driving the conveyor belt to rotate, thus realizing automatic conveying. The movable carriage slides on the fixed slide rail, which can automatically adjust the displacement. The longitudinal cylinder is fixed to the connecting block, and the connecting block fixes the vertical cylinder. The extension and retraction of the longitudinal cylinder and the vertical cylinder can realize the displacement adjustment. The sleeve column fixes the rotary motor. When the rotary motor starts, it drives the rotating ring to rotate, realizing the lateral rotation adjustment. When the rotary motor starts, it drives the rotating shaft to rotate, realizing the vertical rotation adjustment. The movable clamping plate slides on the bidirectional slide rail frame to fix and clamp the parts. Rotation can flip the parts for easy processing and use, completing the automated production of parts processing. Attached Figure Description

[0017] Figure 1 The diagram shown is a three-dimensional structural schematic of the automated production line for parts processing according to this utility model.

[0018] Figure 2 The diagram shown is a schematic of the track of the automated production line for parts processing according to this utility model;

[0019] Figure 3 The diagram shown is a schematic of the partition plate of the automated production line for parts processing according to this utility model;

[0020] Figure 4 The diagram shown is a schematic of a laser engraving tool for an automated production line used in parts processing according to this utility model.

[0021] Explanation of reference numerals in the attached drawings: 1. Base plate; 2. L-shaped frame; 3. Vertical push rod; 4. Laser engraving knife; 5. Protective sleeve; 6. Grinding motor; 7. Grinding shaft; 8. Grinding head; 901. Fixing groove; 902. Partition plate; 903. Conveyor motor; 904. Conveyor shaft; 905. Track; 906. Rotating roller; 907. Conveyor belt; 908. Fixed slide rail; 909. Moving slide; 910. Longitudinal cylinder; 911. Connecting block; 912. Vertical cylinder; 913. Sleeve column; 914. Rotary motor; 915. Rotating ring frame; 916. Rotating motor; 917. Rotating shaft; 918. Two-way slide rail frame; 919. Moving clamping plate. Detailed Implementation

[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0023] Among the currently identified feasible technologies, there are those concerning automated production lines for parts processing.

[0024] I. Composition and Function

[0025] Feeding and unloading system

[0026] The feeding system is responsible for accurately transporting raw materials or blank parts to the starting processing station of the production line. Common feeding methods include vibratory feeder feeding and conveyor belt feeding. For example, vibratory feeder feeding uses vibration to arrange small parts in a certain pattern and transport them one by one to a designated position, which is suitable for parts with relatively regular shapes and small volumes; conveyor belt feeding can be used to transport larger or heavier blanks, and can smoothly deliver them to the processing start point.

[0027] Material handling system: After parts processing is completed, finished or semi-finished parts are systematically removed from the end of the production line. This may involve methods such as robotic gripping or conveyor belt transport to designated collection areas. For example, a robotic arm can precisely grasp parts based on their shape, weight, and other characteristics, and then place them on a material handling conveyor belt or in a finished product storage area.

[0028] Processing equipment integration

[0029] Automated production lines integrate various processing equipment based on the specific processing requirements of the parts. For example, for metal parts processing, there may be CNC lathes, CNC milling machines, machining centers, and grinding machines. CNC lathes can be used to turn the outer diameter and inner diameter of shaft parts; CNC milling machines can perform surface milling, grooving, and other machining operations on parts; machining centers are highly integrated processing equipment that can complete multiple processing operations on a single machine, such as milling, drilling, and boring; grinding machines are used to grind the surface of parts to improve surface accuracy. These processing devices work collaboratively through an automated control system, continuously processing parts according to a preset processing sequence and parameters.

[0030] Detection and Feedback System

[0031] Inspection Equipment: During the parts processing, multiple inspection points are set up, equipped with various inspection devices to monitor the processing quality of the parts in real time. Common inspection equipment includes coordinate measuring machines (CMMs) for accurately measuring the dimensional and shape accuracy of parts; surface roughness testers for detecting the surface roughness of parts; and hardness testers for measuring the hardness and other material properties of parts.

[0032] Feedback Mechanism: The detection system feeds back the results to the control system in real time. If a part is found to be non-compliant with quality requirements, the control system will make corresponding adjustments based on the feedback information, such as pausing the production line, correcting the parameters of the processing equipment, or directly rejecting the non-compliant part to ensure that only qualified parts enter the next process.

[0033] control system

[0034] As the "brain" of an automated production line, the control system is responsible for scheduling and managing the entire production line's operation. It typically uses a programmable logic controller (PLC) or an industrial computer as its control core. It can set the operating parameters of each processing device, such as speed and feed rate; coordinate the working sequence between devices to ensure smooth flow of parts between processing stations; monitor the production line's operating status, including equipment malfunctions and material conveying, and can promptly issue alarms and take corresponding measures to ensure the normal operation of the production line.

[0035] II. Advantages

[0036] Improve processing efficiency

[0037] Automated production lines enable continuous parts processing, reducing time wasted on manual operations such as tool changes, equipment adjustments, and parts handling. The seamless integration of various processing devices allows parts to flow rapidly between different processing steps, significantly shortening the processing time for individual parts and thus improving overall processing efficiency. For example, producing a certain mechanical part might take several days using traditional manual methods, while an automated production line could complete the process in just a few hours.

[0038] Improve processing quality

[0039] Because the processing equipment operates according to preset precise parameters, and the quality is monitored in real time through a detection and feedback system during processing, errors that may be caused by manual operation are reduced, thus ensuring better dimensional accuracy, shape accuracy, and surface quality of the parts. For example, CNC machining equipment can achieve precision down to the micrometer level or even higher, guaranteeing high-quality machining of parts.

[0040] Reduce labor costs

[0041] Automated production lines replace a large number of manual operations, such as loading and unloading parts and simple processing operations, reducing reliance on labor and thus lowering labor costs. Although some initial investment is required in equipment purchase, installation, and commissioning, in the long run, the reduction in labor costs is very significant for large-scale parts processing and production.

[0042] Enhance production stability

[0043] The control system provides comprehensive monitoring and management of the production line, ensuring its stable operation. Even in the event of equipment malfunctions, the control system can promptly detect and take measures, such as switching to backup equipment or adjusting the processing sequence, so that the production process is not interrupted due to individual problems, thus guaranteeing the stability and continuity of production.

[0044] III. Application Cases

[0045] Automotive parts processing

[0046] In automobile manufacturing, many components, such as engine blocks, crankshafts, and transmission gears, are processed using automated production lines. Taking engine blocks as an example, the blank block is first transported to the production line via a loading system. Then, it undergoes multiple machining processes, including turning the outer diameter on a CNC lathe, milling the planes and grooves on a CNC milling machine, and drilling and boring on a machining center. During processing, quality is monitored in real time by inspection equipment. Finally, the finished block is removed from the production line via an unloading system. This automated production method improves the processing quality and efficiency of engine blocks, meeting the large-scale demands of automobile production.

[0047] Electronic component processing

[0048] Automated production lines also play a crucial role in the processing of electronic components such as chips and circuit boards. For example, in chip manufacturing, a series of processes, from silicon wafer cutting, photolithography, and etching to packaging, can be completed using automated production lines. The loading system transports the silicon wafers to the production line, where they are processed by various high-precision equipment. Quality is monitored during processing using inspection equipment, and finally, the unloading system removes the packaged chips from the production line. This method ensures high-quality chip processing and rapid production, meeting the large demand for chips in the electronics industry.

[0049] IV. Development Trends

[0050] Intelligent and Adaptive

[0051] With the development of technologies such as artificial intelligence and big data, automated production lines for parts processing will become increasingly intelligent. Future production lines will be able to automatically adjust the parameters of processing equipment and optimize the processing sequence based on the actual processing conditions of the parts. For example, by analyzing inspection data and discovering that the processing accuracy of a certain part is insufficient, the production line can automatically adjust parameters such as the feed rate or rotation speed of the relevant equipment to improve processing accuracy. At the same time, the production line can also adaptively change the processing flow and equipment configuration according to different types of parts, achieving more flexible production.

[0052] Flexible production

[0053] The diversification of market demand requires automated parts processing production lines to possess flexible production capabilities. This means the production line can quickly switch from processing one type of part to processing another. This can be achieved through rapid mold changes, adjustments to equipment parameters, and reprogramming. For example, in machinery manufacturing enterprises, there is a need to process both shaft-type and disc-type parts; future automated production lines will be able to quickly switch processing modes to meet the processing requirements of different parts.

[0054] Green and environmentally friendly

[0055] Increased environmental awareness has prompted automated parts processing production lines to place greater emphasis on green and environmentally friendly practices in their design and operation. On the one hand, this involves adopting energy-saving equipment to reduce energy consumption, such as selecting low-energy processing equipment and optimizing the power configuration of the conveyor system. On the other hand, it involves reducing pollutant emissions, for example, by using environmentally friendly cutting fluids and effectively recycling and treating waste generated during processing, thus achieving sustainable development.

[0056] Automated production lines for parts processing play an important role in modern manufacturing. With the continuous development of technology, their performance and functions will continue to be improved and expanded.

[0057] Please see Figures 1-4This utility model provides an embodiment: an automated production line for parts processing, including a base plate 1 and an automatic assembly. The base plate 1 is located at the front end of a fixing groove 901. L-shaped frames 2 are located on both sides of the upper end of the base plate 1. Vertical push rods 3 are mounted on the L-shaped frames 2. The L-shaped frames 2 and vertical push rods 3 are arranged as a group, and there are two groups in total, which are respectively located on both sides of the upper end of the base plate 1. A laser engraving knife 4 is located at the lower end of one vertical push rod 3. A protective sleeve 5 is located at the lower end of the other vertical push rod 3. A grinding motor 6 is located inside the protective sleeve 5. A grinding shaft 7 is drivenly connected to the lower end of the grinding motor 6. A grinding head 8 is located at the lower end of the grinding shaft 7. The base plate 1 fixes the L-shaped frame 2, the L-shaped frame 2 fixes the vertical push rod 3, the vertical push rod 3 can extend and retract to realize height adjustment, the laser engraving knife 4 performs the first processing of the part, the protective sleeve 5 protects the grinding motor 6, the grinding motor 6 starts, driving the grinding shaft 7 and the grinding head 8 to rotate, realizing the second processing of the part.

[0058] Please see Figures 1-4This utility model provides an embodiment: An automatic component for automated production is provided at the rear end of the base plate 1. The automatic component includes a fixed groove 901, with a partition 902 between the fixed grooves 901. A transmission motor 903 is provided at the lower end of the front end of the fixed groove 901. A transmission shaft 904 is drivenly connected to the transmission motor 903. A track 905 is tightly attached to the outside of the transmission shaft 904. A rotating roller 906 is provided on the transmission shaft 904. A conveyor belt 907 is provided outside the rotating roller 906. A fixed slide rail 908 is provided at the rear end of the fixed groove 901. A movable slide 909 is slidably connected to the fixed slide rail 908. A longitudinal cylinder 910 is provided at the front end of the movable slide 909. A connecting block 911 is provided at the front end of the longitudinal cylinder 910. A vertical cylinder 912 is provided on the connecting block 911. A sleeve 913 is provided at the lower end of the vertical cylinder 912. A rotary motor 914 is installed inside the sleeve column 913. A rotary ring frame 915 is driven to the lower end of the rotary motor 914. A rotary motor 916 is installed on one side of the rotary ring frame 915. A rotary shaft 917 is driven to the rotary motor 916. A bidirectional slide rail frame 918 is installed on the rotary shaft 917. A movable clamping plate 919 is slidably connected to the bidirectional slide rail frame 918. When the conveyor motor 903 is started, it drives the conveyor shaft 904 and the rotating roller 906 to rotate, thereby automatically rotating the conveyor belt 907 to achieve conveying. Then, when the rotary motor 914 is started, it drives the rotary ring frame 915 to rotate, achieving rotation in the horizontal direction. When the rotary motor 916 is started, it drives the rotary shaft 917 to rotate, achieving rotation in the vertical direction. The movable clamping plate 919 slides and clamps the parts on the bidirectional slide rail frame 918, and the clamped parts can then be flipped. The fixing groove 901 is shaped like an isosceles trapezoid with a slot in the middle. The conveyor motor 903, the conveyor shaft 904, and the rotating roller 906 are arranged as one group and are located at the lower end of the fixed groove 901. The conveyor shaft 904 and the rotating roller 906 are arranged as another group and are located at the upper end of the fixed groove 901. The two groups are connected by a track 905. The two groups are located on one side of the device, and there are two complete sets of the device. The two sets are arranged symmetrically.Fixed slot 901 fixes partition 902. The conveyor motor 903 starts, driving the conveyor shaft 904 and the rotating roller 906 to rotate. The track 905 is connected to the shaft, driving the conveyor belt 907 to rotate, thus realizing automatic conveying. The movable slide 909 slides on the fixed slide rail 908, which can automatically adjust the displacement. The longitudinal cylinder 910 fixes the connecting block 911, and the connecting block 911 fixes the vertical cylinder 912. The extension and retraction of the longitudinal cylinder 910 and the vertical cylinder 912 can realize the displacement adjustment. The sleeve 913 fixes the rotary motor 914. The rotary motor 914 starts, driving the rotary ring frame 915 to rotate, realizing the lateral rotation adjustment. The rotary motor 916 starts, driving the rotating shaft 917 to rotate, realizing the vertical rotation adjustment. The movable clamping plate 919 slides on the bidirectional slide rail frame 918 to fix and clamp the parts. Rotation can flip the parts for easy processing and use.

[0059] During operation, the base plate 1 fixes the L-shaped frame 2, the L-shaped frame 2 fixes the vertical push rod 3, the vertical push rod 3 extends and retracts to adjust the height, the laser engraving knife 4 performs the first processing of the part, the protective sleeve 5 protects the grinding motor 6, the grinding motor 6 starts, driving the grinding shaft 7 and the grinding head 8 to rotate, and realize the second processing of the part. Fixed slot 901 fixes partition 902. Conveyor motor 903 starts, driving conveyor shaft 904 and roller 906 to rotate. Track 905 is connected to drive conveyor belt 907 to rotate, thus realizing automatic conveying. Movable slide 909 slides on fixed slide rail 908, which can automatically adjust displacement. Longitudinal cylinder 910 fixes connecting block 911, and connecting block 911 fixes vertical cylinder 912. The extension and retraction of longitudinal cylinder 910 and vertical cylinder 912 can realize displacement adjustment. Sleeve column 913 fixes rotary motor 914. Rotary motor 914 starts, driving rotary ring frame 915 to rotate, realizing lateral rotation adjustment. Rotary motor 916 starts, driving rotary shaft 917 to rotate, realizing vertical rotation adjustment. Movable clamping plate 919 slides on bidirectional slide rail frame 918 to fix and clamp parts. Rotation can flip parts for easy processing and use, completing all work.

[0060] Through the above steps, by setting the fixed slot 901 to fix the partition 902, the conveyor motor 903 is started, driving the conveyor shaft 904 and the rotating roller 906 to rotate. The track 905 is connected to the shaft, driving the conveyor belt 907 to rotate, thereby realizing automatic conveying. The movable slide 909 slides on the fixed slide rail 908, which can perform automatic displacement adjustment. The longitudinal cylinder 910 fixes the connecting block 911, and the connecting block 911 fixes the vertical cylinder 912. The extension and retraction of the longitudinal cylinder 910 and the vertical cylinder 912 can realize displacement adjustment. The sleeve 913 fixes the rotary motor 914. The rotary motor 914 is started, driving the rotary ring frame 915 to rotate, realizing lateral rotation adjustment. The rotary motor 916 is started, driving the rotating shaft 917 to rotate, realizing vertical rotation adjustment. The movable clamping plate 919 slides on the bidirectional slide rail frame 918 to fix and clamp the parts. Rotation can flip the parts for easy processing and use. It overcomes the shortcomings of existing automated production lines, which can only process one side of the parts at most. After all the parts have been processed on one side, they need to be automatically transferred again to process the other side, resulting in a large workload and difficulty in processing.

[0061] The embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the present invention is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present invention.

Claims

1. An automated production line for parts processing, comprising a base plate (1), characterized in that: It also includes an automatic component. The rear end of the base plate (1) is provided with an automatic component for automated production. The automatic component includes a fixed groove (901), a partition (902) is provided between the fixed grooves (901), a conveyor motor (903) is provided at the lower end of the front end of the fixed groove (901), a conveyor shaft (904) is driven and connected to the conveyor motor (903), a track (905) is provided close to the outside of the conveyor shaft (904), and a rotating roller (906) is provided on the conveyor shaft (904). A conveyor belt (907) is provided on the outside of the rotating roller (906). A fixed slide rail (908) is provided at the rear end of the fixed groove (901). A movable slide (909) is slidably connected to the fixed slide rail (908). A longitudinal cylinder (910) is provided at the front end of the movable slide (909). A connecting block (911) is provided at the front end of the longitudinal cylinder (910). A vertical cylinder (912) is provided on the connecting block (911). A sleeve (913) is provided at the lower end of the vertical cylinder (912). The sleeve (913) is equipped with a rotary motor (914) inside. The lower end of the rotary motor (914) is connected to a rotary ring frame (915). A rotary motor (916) is installed on one side of the rotary ring frame (915). A rotary shaft (917) is connected to the rotary motor (916). A two-way slide rail frame (918) is installed on the rotary shaft (917). A movable clamping plate (919) is slidably connected to the two-way slide rail frame (918). The conveyor motor (903) is started to drive the conveyor. The shaft (904) and the roller (906) rotate, driving the conveyor belt (907) to rotate automatically, thus realizing the conveying work. Then, the set rotary motor (914) is started, driving the rotating ring frame (915) to rotate, thus realizing the rotation in the horizontal direction. The rotary motor (916) is started, driving the rotating shaft (917) to rotate, thus realizing the rotation in the vertical direction. The parts are clamped by sliding the moving clamping plate (919) on the bidirectional slide rail frame (918), and then the clamped parts can be flipped.

2. The automated production line for parts processing according to claim 1, characterized in that: The fixing groove (901) is set in the shape of an isosceles trapezoid and has a slot in the middle.

3. The automated production line for parts processing according to claim 1, characterized in that: The conveyor motor (903), the conveyor shaft (904) and the rotating roller (906) are set as one group and are located at the lower end of the fixed groove (901). The conveyor shaft (904) and the rotating roller (906) are set as another group and are located at the upper end of the fixed groove (901). The two groups are connected by a track (905).

4. The automated production line for parts processing according to claim 3, characterized in that: Two sets are set on one side of the device, and there are two complete sets in total, which are arranged symmetrically.

5. An automated production line for parts processing according to claim 1, characterized in that: The front end of the fixed groove (901) is provided with a base plate (1), and the upper end of the base plate (1) is provided with L-shaped frames (2) on both sides. The L-shaped frames (2) are provided with vertical push rods (3). The L-shaped frames (2) and the vertical push rods (3) are set as a group, and there are two groups in total. The two groups are respectively set on both sides of the upper end of the base plate (1).

6. An automated production line for parts processing according to claim 5, characterized in that: A laser engraving tool (4) is provided at the lower end of the vertical push rod (3) on one side.

7. An automated production line for parts processing according to claim 5, characterized in that: A protective sleeve (5) is provided at the lower end of the vertical push rod (3) on the other side. A grinding motor (6) is provided inside the protective sleeve (5). A grinding shaft (7) is connected to the lower end of the grinding motor (6). A grinding head (8) is provided at the lower end of the grinding shaft (7).