A high-precision metal piece production device
By designing automated, high-precision metal parts production equipment, the system enables the classified collection and reuse of metal shavings and wastewater, solving the problems of resource waste and low efficiency, and improving production efficiency and processing precision.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIAXING JINGLUN INTELLIGENT TECHNOLOGY CO LTD
- Filing Date
- 2025-07-14
- Publication Date
- 2026-07-07
Smart Images

Figure CN224463832U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of metal parts production equipment technology, specifically to a high-precision metal parts production equipment. Background Technology
[0002] High-precision metal parts refer to metal components that possess extremely high accuracy and meet stringent specifications. These parts typically need to be manufactured within micrometer-level or even smaller dimensional tolerances to ensure their accuracy and reliability during assembly and use. High-precision metal parts are widely used in high-tech products, requiring not only high functionality but also aesthetic appeal. For example, the metal casings and internal frames of electronic products such as mobile phones and computers need to achieve micrometer-level accuracy to ensure the installation precision and stability of electronic components, while also providing a good appearance and feel.
[0003] Existing high-precision metal parts production equipment generates a large amount of metal shavings and wastewater during processing. These shavings and wastewater are often discharged together, with the wastewater being drained first and the metal shavings collected later. This process is not highly automated and requires frequent manual intervention, leading to resource waste and reduced production efficiency. Therefore, it is particularly important to improve existing high-precision metal parts production equipment and design a new type of high-precision metal parts production equipment to address the above-mentioned technical deficiencies and improve the overall practicality of high-precision metal parts production equipment. Utility Model Content
[0004] The purpose of this invention is to provide a high-precision metal parts production equipment. This equipment can automatically classify and collect the metal shavings and wastewater generated during the processing of high-precision metal parts, and then reuse them, thereby improving resource utilization, increasing work efficiency, saving resources and protecting the environment. At the same time, it can automatically change the processing angle and adapt to various specifications of high-precision metal parts, thereby improving the production efficiency of high-precision metal parts and enhancing the overall practicality of the high-precision metal parts production equipment, thus solving the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution:
[0006] A high-precision metal parts production equipment includes a main body, the main body having a working chamber and a partition chamber inside. A rotating table is rotatably connected inside the working chamber, and a first electric telescopic rod is fixedly connected to one end of the top of the rotating table. A sieve plate is slidably connected inside the partition chamber, and multiple sets of discharge holes are opened on the top of the sieve plate. A vibrating motor is fixedly connected to the bottom of the sieve plate inside the partition chamber. A collection box is fixedly connected to the bottom of the vibrating motor inside the partition chamber. A conveyor belt is rotatably connected inside the collection box, and multiple sets of water outlet holes are opened on the top of the conveyor belt. A receiving cart is located at the bottom of the end of the conveyor belt extending outside the main body. A rotating rod is rotatably connected inside the sieve plate. A fourth motor is fixedly connected to the top of the partition chamber. Two sets of scrapers are fixedly connected to the top of the rotating rod inside the partition chamber, and two sets of scraper bars are fixedly connected to the outer end of the rotating rod near the sieve plate.
[0007] As a preferred embodiment of this utility model, the side of the first electric telescopic rod closest to the center of the rotating table is the driving end, the end of the vibrating motor closest to the sieve plate is the driving end and is in contact with the sieve plate, and the driving end of the fourth motor extends into the interior of the partition chamber and is fixedly connected to the rotating rod.
[0008] As a preferred embodiment of this utility model, a first nozzle is fixedly connected to the inside of the working chamber and on the side away from the partition chamber, a second nozzle is fixedly connected to the inside of the partition chamber, a water tank is fixedly connected to the inside of the working chamber and at the bottom of the rotating platform, and an inlet pipe and two sets of connecting pipes are fixedly connected inside the water tank. The two sets of connecting pipes are respectively connected to the first nozzle and the second nozzle away from the water tank.
[0009] As a preferred embodiment of this utility model, the top of the receiving cart is provided with a collection trough, and a rotating door is rotatably connected to the inside of the collection trough and the side closest to the main body. The bottom of the receiving cart is provided with a fixing groove, and a third electric telescopic rod is fixedly connected inside the fixing groove. A connecting plate is slidably connected inside the fixing groove and at the bottom of the third electric telescopic rod. Multiple sets of universal wheels are fixedly connected to the bottom of the connecting plate. The end of the third electric telescopic rod near the connecting plate is the driving end and is fixedly connected to the connecting plate.
[0010] As a preferred embodiment of this utility model, a filter box is fixedly connected to the bottom of the collection box and the end near the working chamber. A drain pipe is fixedly connected to the end of the filter box away from the receiving cart. A water pump is fixedly connected inside the main body and between the collection box and the water tank. The suction end of the water pump extends into the interior of the filter box, and the outlet end of the water pump extends into the interior of the water tank.
[0011] As a preferred embodiment of this utility model, a first motor is fixedly connected inside the working chamber and between the rotating platform and the water tank. The drive end of the first motor is fixedly connected to the rotating platform. Second electric telescopic rods are fixedly connected inside the working chamber and on both sides of the rotating platform. The ends of the two sets of second electric telescopic rods that are close to each other are drive ends and are fixedly connected to second motors. The ends of the two sets of second motors that are close to each other are drive ends and are fixedly connected to electric grippers. A hydraulic press is fixedly connected inside the working chamber and at the top of the rotating platform. The end of the hydraulic press near the rotating platform is a drive end and is fixedly connected to a third motor. The end of the third motor near the rotating platform is a drive end and is fixedly connected to a cutting tool. A camera is fixedly connected to the top of the working chamber and near the partition chamber.
[0012] As a preferred embodiment of this utility model, the interior of the main body is provided with a sound insulation layer. The interior of the sound insulation layer is vacuum-designed and contains sound-absorbing cotton. An electric lifting rod is fixedly connected to the interior of the main body, on the side between the working chamber and the partition chamber, and on the side of the working chamber and the partition chamber that are far apart from each other. The end of the electric lifting rod near the water tank is the driving end and is fixedly connected to a baffle.
[0013] Compared with the prior art, the beneficial effects of this utility model are:
[0014] 1. In this utility model, through the design of the main body, working chamber, partition chamber, first nozzle, water tank, water inlet pipe, connecting pipe, second nozzle, rotating table, first electric telescopic rod, sieve plate, discharge hole, vibrating motor, collection box, conveyor belt, water outlet, receiving cart, collection trough, rotating door, fixing trough, third electric telescopic rod, connecting plate, universal wheel, filter box, drain pipe, water pump, fourth motor, rotating rod, scraper and scraper rod, when the high-precision metal parts production equipment is put into use, it can automatically classify and collect the metal shavings and wastewater generated during the processing of high-precision metal parts, and then reuse them, thereby improving resource utilization, increasing work efficiency, saving resources and protecting the environment. It can also prevent metal shavings from forming blockages and adhering inside, thus saving raw materials.
[0015] 2. In this utility model, through the design of the main body, working chamber, first nozzle, first motor, rotating table, first electric telescopic rod, second electric telescopic rod, second motor, electric gripper, hydraulic press, third motor, cutting tool and camera, when the production equipment for high-precision metal parts is put into use, the camera captures the processing process, which facilitates timely adjustment, improves processing accuracy, can automatically change the processing angle and adapt to high-precision metal parts of various specifications, and improves the production efficiency of high-precision metal parts. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0017] Figure 2 This is a schematic diagram of the side cross-sectional structure of the main body of this utility model;
[0018] Figure 3 This is a schematic diagram of the material receiving cart structure of this utility model;
[0019] Figure 4 This is a side cross-sectional view of the material receiving cart of this utility model.
[0020] In the diagram: 1. Main body; 101. Workshop; 102. Partitioned room; 103. Sound insulation layer; 2. First nozzle; 201. Water tank; 202. Inlet pipe; 203. Connecting pipe; 204. Second nozzle; 3. First motor; 301. Rotating table; 302. First electric telescopic rod; 4. Second electric telescopic rod; 401. Second motor; 403. Electric gripper; 5. Hydraulic press; 501. Third motor; 502. Cutting tool; 503. Camera; 6. Screen plate; 60 1. Discharge port; 602. Vibrating motor; 603. Collection box; 604. Conveyor belt; 605. Water outlet; 7. Receiving cart; 701. Collection trough; 702. Rotating door; 703. Fixed trough; 704. Third electric telescopic rod; 705. Connecting plate; 706. Casters; 8. Filter box; 801. Drain pipe; 802. Water pump; 9. Fourth motor; 901. Rotating rod; 902. Scraper; 903. Scraper bar; 904. Electric lifting rod; 905. Baffle. Detailed Implementation
[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.
[0022] Example:
[0023] Please see Figures 1-4 This utility model provides a technical solution:
[0024] A high-precision metal parts production equipment includes a main body 1. The main body 1 has a working chamber 101 and a partition chamber 102 inside. A rotating table 301 is rotatably connected inside the working chamber 101. A first electric telescopic rod 302 is fixedly connected to one end of the top of the rotating table 301. A sieve plate 6 is slidably connected inside the partition chamber 102. Multiple sets of discharge holes 601 are opened on the top of the sieve plate 6. A vibration motor 602 is fixedly connected to the bottom of the sieve plate 6 inside the partition chamber 102. A collection box 603 is fixedly connected to the bottom of the vibration motor 602 inside the partition chamber 102. A conveyor belt 604 is rotatably connected inside the collection box 603. Multiple sets of water outlet holes 605 are opened on the top of the conveyor belt 604. The conveyor belt 604 extends to... A material receiving cart 7 is provided at the bottom of one end of the main body 1. A rotating rod 901 is rotatably connected inside the screen plate 6. A fourth motor 9 is fixedly connected to the top of the partition chamber 102. Two sets of scrapers 902 are fixedly connected to the top of the rotating rod 901 inside the partition chamber 102. Two sets of scraper bars 903 are fixedly connected to the end of the rotating rod 901 near the screen plate 6. The drive end of the first electric telescopic rod 302 is near the center of the rotating table 301. The drive end of the vibrating motor 602 is near the screen plate 6 and is in contact with the screen plate 6. The drive end of the fourth motor 9 extends into the partition chamber 102 and is fixedly connected to the rotating rod 901. A first nozzle 2 is fixedly connected to the inside of the working chamber 101 away from the partition chamber 102. A second nozzle 204 is fixedly connected to one side of the partition chamber 102. A water tank 201 is fixedly connected inside the working chamber 101 and at the bottom of the rotating table 301. A water inlet pipe 202 and two sets of connecting pipes 203 are fixedly connected inside the water tank 201. The two sets of connecting pipes 203 are connected to the first nozzle 2 and the second nozzle 204 respectively, away from the water tank 201. When the high-precision metal part production equipment is put into use, the power is turned on, and the high-precision metal part is placed on the rotating table 301 for processing. The first nozzle 2 draws water from the water tank 201 and sprays it onto the rotating table 301, thereby reducing the temperature at the processing area and flushing the metal debris generated during processing into the partition chamber 102, so that the metal debris enters the conveyor belt 604 from the discharge hole 601. The metal parts are then transported by conveyor belt 604 to the receiving cart 7 for easy recycling. Water droplets enter the water outlet 605 from the discharge hole 601 and then enter the collection box 603. The drive end of the vibrating motor 602 vibrates, thereby causing the screen plate 6 to vibrate, thus preventing the discharge hole 601 from clogging. The drive end of the fourth motor 9 rotates, thereby driving the rotating rod 901 to rotate, which in turn drives the scraper 902 and scraper 903 to rotate, thus scraping off the metal shavings and preventing them from adhering to the inner wall, saving raw materials. The processed high-precision metal parts are pushed into the partition chamber 102 by the drive end of the first electric telescopic rod 302. The second nozzle 204 sprays water again to clean them, thus ensuring the cleanliness of the high-precision metal parts and further emptying the metal shavings inside the partition chamber 102.It can automatically separate and recycle finished high-precision metal parts, metal shavings, and water, improving resource utilization and work efficiency.
[0025] Furthermore, the top of the receiving cart 7 is provided with a collection trough 701, and a rotating door 702 is rotatably connected to the inside of the collection trough 701 and the side closest to the main body 1. The bottom of the receiving cart 7 is provided with a fixing groove 703, and a third electric telescopic rod 704 is fixedly connected inside the fixing groove 703. A connecting plate 705 is slidably connected inside the fixing groove 703 and at the bottom of the third electric telescopic rod 704. Multiple sets of universal wheels 706 are fixedly connected to the bottom of the connecting plate 705. The end of the third electric telescopic rod 704 near the connecting plate 705 is the driving end and is fixedly connected to the connecting plate 705. When the high-precision... When the metal parts production equipment is put into use, the power is turned on, and the conveyor belt 604 transports the metal scraps to the receiving cart 7. The drive end of the third electric telescopic rod 704 retracts, thereby driving the connecting plate 705 to rise, which in turn retracts the casters 706 into the fixed groove 703, thus fixing the receiving cart 7 in place, making it difficult for the receiving cart 7 to move when collecting metal scraps. The drive end of the third electric telescopic rod 704 descends, thereby driving the connecting plate 705 to descend, which pushes the multiple sets of casters 706 out of the fixed groove 703, thus facilitating the movement and transportation of metal scraps. The rotating door 702 is then opened to facilitate the removal of the metal scraps.
[0026] The collection box 603 is fixedly connected to a filter box 8 at the bottom and near the working chamber 101. The filter box 8 is fixedly connected to a drain pipe 801 at the end away from the receiving cart 7. A water pump 802 is fixedly connected inside the main body 1 between the collection box 603 and the water tank 201. The suction end of the water pump 802 extends into the interior of the filter box 8, and the outlet end of the water pump 802 extends into the interior of the water tank 201. When the high-precision metal parts production equipment is put into use, the power is turned on, the water in the collection box 603 is filtered by the filter box 8, the concentrated water is discharged from the drain pipe 801, and the water pump 802 transports the filtered water to the water tank 201 for reuse, which improves the efficiency of water resource utilization and saves water and protects the environment.
[0027] Secondly, a first motor 3 is fixedly connected inside the workshop 101, between the rotating table 301 and the water tank 201. The drive end of the first motor 3 is fixedly connected to the rotating table 301. Second electric telescopic rods 4 are fixedly connected inside the workshop 101, on both sides of the rotating table 301. The ends of the two sets of second electric telescopic rods 4 closest to each other are drive ends, and each is fixedly connected to a second motor 401. The ends of the two sets of second motors 401 closest to each other are drive ends, and each is fixedly connected to an electric gripper 403. A hydraulic press 5 is fixedly connected inside the workshop 101, on top of the rotating table 301. The end of the hydraulic press 5 closest to the rotating table 301 is the drive end, and a third motor 501 is fixedly connected. The end of the third motor 501 closest to the rotating table 301 is the drive end, and a cutting tool 502 is fixedly connected. A camera 503 is fixedly connected to the top of the workshop 101, near the partition chamber 102. When this high-precision metal parts production equipment is put into operation... When in use, the power is turned on, and the high-precision metal parts to be processed are placed on the rotating table 301. The drive end of the first motor 3 rotates, thereby driving the rotating table 301 to rotate, thus changing the processing angle of the high-precision metal parts. The drive ends of the two sets of second electric telescopic rods 4 move towards each other, thereby driving the two sets of electric grippers 403 to move towards each other, thus clamping high-precision metal parts of various specifications. The drive end of the second motor 401 rotates, thereby driving the electric grippers 403 to rotate, thus changing the processing angle of the high-precision metal parts. The drive end of the hydraulic press 5 descends, thereby driving the cutting tool 502 to descend, thus processing high-precision metal parts of different specifications. The drive end of the third motor 501 rotates, thereby driving the cutting tool 502 to rotate, thus changing the processing angle. The camera 503 captures the processing process, facilitating timely adjustments, improving processing accuracy, automatically changing the processing angle and adapting to various specifications of high-precision metal parts, thus improving the production efficiency of high-precision metal parts.
[0028] Furthermore, the main body 1 has a sound insulation layer 103 inside. The sound insulation layer 103 is vacuum-designed and contains sound-absorbing cotton. Electric lifting rods 904 are fixedly connected to the inside of the main body 1, between the working chamber 101 and the partition chamber 102, on the side of the working chamber 101 and the partition chamber 102 that are far apart from each other. The end of the electric lifting rod 904 near the water tank 201 is the drive end and is fixedly connected to a baffle 905. When the production equipment for this high-precision metal parts is put into use, the vacuum-designed sound insulation layer 103 reduces the sound propagation, and the sound-absorbing cotton absorbs some of the noise, thereby reducing the impact of the noise generated inside the main body 1 during operation on the outside world, ensuring the life, health and safety of the workers. When the main body 1 is running, the drive ends of multiple sets of electric lifting rods 904 descend, thereby driving the baffle 905 to descend, thereby reducing the transmission of noise to the outside world, and also reducing the interference generated by the outside world on the inside of the main body 1, improving processing efficiency.
[0029] The control method of this utility model is through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art. The power supply is also common knowledge in the field. Since this utility model is used to protect mechanical devices, the control method and circuit connection will not be explained in detail.
[0030] In this embodiment, the specific implementation scenario is as follows: In actual use, when the production equipment for the high-precision metal parts is put into use, the power is turned on, and the high-precision metal parts to be processed are placed on the rotating table 301. The drive end of the first motor 3 rotates, thereby driving the rotating table 301 to rotate, thus changing the processing angle of the high-precision metal parts. The drive ends of the two sets of second electric telescopic rods 4 move towards each other, thereby driving the two sets of electric grippers 403 to move towards each other, thus being able to clamp high-precision metal parts of various specifications. The drive end of the second motor 401 rotates, thereby driving the electric grippers 403 to rotate, thus changing the processing angle of the high-precision metal parts. The drive end of the hydraulic press 5 descends, thereby driving the cutting tool 502 to descend, thus processing high-precision metal parts of different specifications. The workpiece is processed by rotating the drive end of the third motor 501, which in turn drives the tool 502 to rotate, thereby changing the processing angle. The camera 503 captures the processing process, facilitating timely adjustments and improving processing accuracy. It can automatically change the processing angle and is suitable for various specifications of high-precision metal parts, thus improving the production efficiency of high-precision metal parts. The first nozzle 2 draws water from the water tank 201 and sprays it onto the rotating table 301, thereby reducing the temperature at the processing area and flushing the metal debris generated during processing into the partition chamber 102. This allows the metal debris to enter the conveyor belt 604 from the discharge hole 601 and then be transported by the conveyor belt 604 to the receiving car 7 for easy recycling. Water droplets enter the water outlet 605 from the discharge hole 601 and then enter the interior of the collection box 603. The vibration motor 602 drives... The end vibration drives the screen plate 6 to vibrate, thus preventing the discharge hole 601 from clogging. The drive end of the fourth motor 9 rotates, which drives the rotating rod 901 to rotate, thereby driving the scraper 902 and scraper 903 to rotate, thus scraping off the metal shavings and preventing them from adhering to the inner wall, saving raw materials. The processed high-precision metal parts are pushed into the partition chamber 102 by the drive end of the first electric telescopic rod 302. The second nozzle 204 sprays water again to clean them, thus ensuring the cleanliness of the high-precision metal parts and further emptying the metal shavings inside the partition chamber 102. It can automatically separate and recycle the processed high-precision metal parts, metal shavings, and water, improving resource utilization and work efficiency. The water in the collection box 603 is filtered by the filter box 8, and the concentrated water is discharged from the outlet. Water is discharged through pipe 801, and water pump 802 transports the filtered water to water tank 201 for reuse, improving water resource utilization efficiency and saving resources. Conveyor belt 604 transports metal scraps to receiving cart 7. The drive end of the third electric telescopic rod 704 descends, thereby driving the connecting plate 705 to descend, which pushes multiple sets of universal wheels 706 out of the fixing groove 703, thus facilitating the movement and transportation of metal scraps. The rotating door 702 is opened to facilitate the removal of metal scraps. The vacuum-designed sound insulation layer 103 reduces sound propagation, and the sound-absorbing cotton absorbs some noise, thereby reducing the impact of noise generated inside the main body 1 during operation on the outside world and ensuring the life, health and safety of workers. During the operation of the main body 1, the drive ends of multiple sets of electric lifting rods 904 descend, thereby driving the baffle 905 to descend.This reduces noise transmission to the outside world and minimizes external interference with the interior of the main body 1, improving processing efficiency. The rising drive end of the electric lifting rod 904 raises the baffle 905, facilitating the collection of processed high-precision metal parts. Compared to existing high-precision metal part production equipment, this invention improves the overall practicality of high-precision metal part production equipment through its design.
[0031] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A high-precision metal parts production equipment, comprising a main body (1), characterized in that: The main body (1) has a working chamber (101) and a partition chamber (102) inside. A rotating table (301) is rotatably connected inside the working chamber (101). A first electric telescopic rod (302) is fixedly connected to one end of the top of the rotating table (301). A screen plate (6) is slidably connected inside the partition chamber (102). Multiple sets of discharge holes (601) are opened on the top of the screen plate (6). A vibration motor (602) is fixedly connected to the bottom of the screen plate (6) and inside the partition chamber (102). A collection box (603) is fixedly connected to the bottom of the vibration motor (602) inside the partition chamber (102). The collection box (603) is rotatably connected to a conveyor belt (604). The top of the conveyor belt (604) has multiple sets of water outlet holes (605). The bottom of the end of the conveyor belt (604) extending to the outside of the main body (1) is provided with a material receiving cart (7). The screen plate (6) is rotatably connected to a rotating rod (901). The top of the partition chamber (102) is fixedly connected to a fourth motor (9). The top of the rotating rod (901) located inside the partition chamber (102) is fixedly connected to two sets of scrapers (902). The end of the rotating rod (901) near the screen plate (6) is fixedly connected to two sets of scrapers (903).
2. The high-precision metal parts production equipment according to claim 1, characterized in that: The first electric telescopic rod (302) has a drive end on the side near the center of the rotating table (301), the vibrating motor (602) has a drive end near the sieve plate (6) and is in contact with the sieve plate (6), and the drive end of the fourth motor (9) extends into the interior of the partition chamber (102) and is fixedly connected to the rotating rod (901).
3. The high-precision metal parts production equipment according to claim 2, characterized in that: A first nozzle (2) is fixedly connected to the inside of the working chamber (101) and to the side away from the partition chamber (102). A second nozzle (204) is fixedly connected to the inside of the partition chamber (102). A water tank (201) is fixedly connected to the inside of the working chamber (101) and to the bottom of the rotating platform (301). An inlet pipe (202) and two sets of connecting pipes (203) are fixedly connected inside the water tank (201). The two sets of connecting pipes (203) are connected to the first nozzle (2) and the second nozzle (204) respectively away from the water tank (201).
4. The high-precision metal parts production equipment according to claim 3, characterized in that: The top of the receiving cart (7) is provided with a collection trough (701). A rotating door (702) is rotatably connected inside the collection trough (701) and on the side closer to the main body (1). The bottom of the receiving cart (7) is provided with a fixing groove (703). A third electric telescopic rod (704) is fixedly connected inside the fixing groove (703). A connecting plate (705) is slidably connected inside the fixing groove (703) and at the bottom of the third electric telescopic rod (704). Multiple sets of universal wheels (706) are fixedly connected to the bottom of the connecting plate (705). The end of the third electric telescopic rod (704) near the connecting plate (705) is the driving end and is fixedly connected to the connecting plate (705).
5. The high-precision metal parts production equipment according to claim 4, characterized in that: A filter box (8) is fixedly connected to the bottom of the collection box (603) and the end near the working chamber (101). A drain pipe (801) is fixedly connected to the end of the filter box (8) away from the receiving cart (7). A water pump (802) is fixedly connected inside the main body (1) and between the collection box (603) and the water tank (201). The suction end of the water pump (802) extends into the interior of the filter box (8), and the outlet end of the water pump (802) extends into the interior of the water tank (201).
6. The high-precision metal parts production equipment according to claim 5, characterized in that: A first motor (3) is fixedly connected inside the working chamber (101) and between the rotating platform (301) and the water tank (201). The drive end of the first motor (3) is fixedly connected to the rotating platform (301). Second electric telescopic rods (4) are fixedly connected inside the working chamber (101) and on both sides of the rotating platform (301). The ends of the two sets of second electric telescopic rods (4) that are close to each other are the drive ends, and each is fixedly connected to a second motor (401). The ends of the two sets of second motors (401) that are close to each other are the drive ends. The moving end is fixedly connected to an electric gripper (403). Inside the working chamber (101) and on top of the rotating platform (301), a hydraulic press (5) is fixedly connected. The end of the hydraulic press (5) near the rotating platform (301) is the driving end and is fixedly connected to a third motor (501). The end of the third motor (501) near the rotating platform (301) is the driving end and is fixedly connected to a cutting tool (502). Inside the working chamber (101), on the top and near the partition chamber (102), a camera (503) is fixedly connected.
7. The high-precision metal parts production equipment according to claim 6, characterized in that: The main body (1) is provided with a sound insulation layer (103) inside. The sound insulation layer (103) is vacuum-designed and has sound-absorbing cotton inside. The main body (1) is fixedly connected with an electric lifting rod (904) on the side of the main body (1) between the working chamber (101) and the partition chamber (102) and the side of the working chamber (101) and the partition chamber (102) that are far away from each other. The end of the electric lifting rod (904) near the water tank (201) is the driving end and is fixedly connected with a baffle (905).