High quality metal forging device
By designing a high-quality metal forging device with a throwing mechanism and stable structure, the problems of complex throwing structure, severe wear, and safety hazards in existing forging equipment have been solved. This has enabled efficient and safe material sliding and equipment stability, thereby improving the durability and economy of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- NANJING IRON & STEEL GRP METALLURGICAL CASTING CO LTD
- Filing Date
- 2025-09-02
- Publication Date
- 2026-07-03
AI Technical Summary
The existing forging equipment's throwing structure has problems such as complex equipment, large footprint, many safety hazards, and severe equipment wear, making it difficult to balance processing accuracy and equipment stability.
A high-quality metal forging device including a throwing mechanism and a stabilizing structure was designed. By cooperating with the wedge-shaped clamping block and the stabilizing groove, the buffering effect of the compression spring, and the linkage structure driven by the servo electric cylinder, the device achieves smooth material sliding and equipment stability, simplifies the power system, and improves throwing efficiency and equipment life.
It significantly improves the material throwing efficiency and safety of the equipment, extends the service life of the equipment, reduces manufacturing costs and floor space, adapts to different material requirements, and improves processing accuracy and equipment durability.
Smart Images

Figure CN120861740B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of forging machinery, specifically a high-quality metal forging device. Background Technology
[0002] Metal forging, as a key metal processing technology, is widely used in machinery manufacturing, automotive industry, aerospace and other fields to produce high-strength, high-precision metal parts. Traditional forging equipment typically uses a hydraulic press to drive a forging hammer to process materials, but its material throwing stage design has significant shortcomings. Existing material throwing structures are mainly divided into two categories: one type uses an independent pushing device to push the forged material out of the worktable. This method requires an additional power system, resulting in a complex equipment structure, increased floor space, and the material is prone to splashing or rapid jumping during lateral movement, posing safety hazards and potentially causing edge damage to the material or impact damage to the floor; the other type lifts the forging base plate to tilt it and allow the material to slide down. However, when the forging base plate is subjected to repeated impacts from the forging hammer, it is prone to slight vibrations and collisions with the receiving platform at the bottom, leading to continuous wear of the receiving platform, forging base plate and other connecting components, significantly shortening the equipment's service life. In addition, existing equipment generally lacks an effective stabilization mechanism, making it difficult to ensure both processing accuracy and equipment durability and long-term operational stability. Therefore, developing a high-quality metal forging device that integrates efficient material throwing, stable forging, and long service life has become a technical problem that the metal forging industry urgently needs to solve. Thus, a high-quality metal forging device is proposed. Summary of the Invention
[0003] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.
[0004] Given the following technical problems in the existing technology: existing forging equipment generally lacks a throwing structure. There are two main types of throwing structures in existing forging equipment. One type directly pushes the forged material away from the worktable. This throwing structure requires a separate power unit, which not only increases the equipment's footprint but may also lead to low efficiency or material splashing. Lateral material movement and the throwing structure are not only dangerous but also easily cause the material to fly rapidly and collide, damaging the material's edges and the floor. The other type is to lift the forging base plate and tilt it, causing the material on the forging base plate to slide off. In this method, when the forging base plate is subjected to the impact of the forging hammer, it is easy for it to experience slight vibrations and impacts with the bottom receiving platform, resulting in continuous damage to the receiving platform, forging base plate, and other connecting parts, affecting their service life.
[0005] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a high-quality metal forging device, including a frame assembly, the frame assembly including a base plate, a frame, a hydraulic press, a hydraulic rod, a forging hammer and a receiving platform, the frame is provided on the upper side of the base plate, the hydraulic press is provided at the top of the frame, the hydraulic rod is provided at the bottom of the hydraulic press, the bottom end of the hydraulic rod passes downward through the top of the frame and connects to the forging hammer, and the receiving platform is provided at the top of the base plate;
[0006] The throwing mechanism includes a drive structure, a forging base plate, a connecting plate, and a vertical frame. A groove is provided at the top of the receiving platform, and the forging base plate is movably connected in the groove. The lower side of the forging base plate is movably connected to the inner bottom wall of the groove of the receiving platform. A vertical frame is provided on each side of the groove. A connecting plate is provided in the inner cavity of the vertical frame. The connecting plate is rotatably connected to the inner wall of the vertical frame. One end of the vertical frame is fixedly connected to the bottom of the forging base plate, and the other end of the connecting plate is connected to the drive structure.
[0007] A stabilizing structure is provided on the forging hammer.
[0008] As a preferred technical solution for a high-quality metal forging device, the throwing mechanism also includes a recovery chamber. The recovery chamber is opened on the front of the receiving platform. The forging base plate is L-shaped and is movably connected to the recovery chamber. The groove is connected to the recovery chamber. By setting the recovery chamber on the receiving platform and movably connecting the L-shaped forging base plate to the recovery chamber, and with the connection design of the groove and the recovery chamber, the material can slide down, avoid the material from scattering, and improve the throwing efficiency and the cleanliness of the operation.
[0009] As a preferred technical solution for a high-quality metal forging device, the stabilizing structure includes a clamping block, a first stabilizing groove, a second stabilizing groove, a connecting ring, a limiting ring, a pressing rod, and a pressing spring. The clamping block is wedge-shaped. Four first stabilizing grooves are formed at the top of the forging base plate, and four second stabilizing grooves are formed on the upper side of the receiving platform. The first and second stabilizing grooves correspond one-to-one. The shape of the top part of the clamping block matches the shape of the first stabilizing groove, and the shape of the bottom part of the clamping block matches the shape of the second stabilizing groove. A connecting ring is set on each side of the forging hammer. A pressing rod is movably inserted into the connecting ring. The bottom end of the pressing rod is fixedly connected to the clamping block. A limiting ring is set at the bottom of the pressing rod. A pressing spring is sleeved on the top of the pressing rod. The top end of the pressing spring is fixedly connected to the lower side of the connecting ring, and the bottom end of the pressing spring is fixedly connected to the upper side of the limiting ring. Through the matching design of the wedge-shaped clamping block with the first and second stabilizing grooves, combined with the buffering effect of the pressing spring, the movement of the forging base plate is effectively restricted, the impact kinetic energy is absorbed, the damage to the forging base plate and the receiving platform is reduced, and the equipment life is significantly extended.
[0010] As a preferred technical solution for a high-quality metal forging device, the stabilizing structure also includes a dust removal chamber. A dust removal chamber is provided on each side of the receiving platform, and a communication channel is provided between the dust removal chamber and the second stabilizing tank. By providing dust removal chambers on both sides of the receiving platform and connecting them with the second stabilizing tank, it is convenient to remove the residue generated during the forging process, keep the equipment clean, reduce wear and failure risks, and improve the stability of equipment operation.
[0011] As a preferred technical solution for a high-quality metal forging device, the throwing mechanism also includes a second connecting shaft. The part of the connecting plate near the forging base plate is rotatably connected to the second connecting shaft. The second connecting shaft is located in the vertical frame and is fixedly installed inside the vertical frame. Through the rotatable connection and fixed installation of the second connecting shaft, the motion stability of the connecting plate and the vertical frame is enhanced, ensuring the accuracy and reliability of the tilting action of the forging base plate.
[0012] As a preferred technical solution for a high-quality metal forging device, the drive structure includes a clamping structure and a linkage structure. The linkage structure includes a vertical frame, a connecting shaft one, and a connecting shaft three. The portion of the connecting plate away from the forging base plate has a movable groove, within which the connecting shaft one is movably connected. The movable groove is a blind groove. The middle section of the connecting shaft one is rotatably connected to two vertical frames, and the connecting shaft three is located between the tops of the two vertical frames, rotatably connected to the vertical frames. Through the design of the connecting shaft one, connecting shaft three, and movable groove in the linkage structure, the smooth tilting movement of the forging base plate is achieved. Combined with the clamping structure, the throwing angle can be precisely controlled to adapt to different material requirements, improving throwing efficiency and flexibility.
[0013] As a preferred technical solution for a high-quality metal forging device, the clamping structure includes a control component and a matching frame. The matching frame is C-shaped. A servo electric cylinder is installed inside the control component, and the matching frame is installed on the movable end of the servo electric cylinder. The matching frame is movably connected to the connecting shaft three. Through the clamping structure design of the C-shaped matching frame and the servo electric cylinder, precise clamping and synchronous movement of the connecting shaft three are achieved, simplifying the material throwing control process and improving the stability and automation of the action.
[0014] As a preferred technical solution for a high-quality metal forging device, the clamping block is wedge-shaped, and the angle between the outer side of the clamping block and the vertical plane is 12 to 15 degrees. By designing the angle between the outer side of the clamping block and the vertical plane to be 12 to 15 degrees, the limiting effect of the wedge structure is optimized, the stability of the forging base plate is enhanced, impact damage is reduced, and forging accuracy is improved.
[0015] As a preferred technical solution for a high-quality metal forging device, the bottom end of the vertical frame located below the connecting shaft is rotatably connected to a roller. The length of the bottom end of the vertical frame located below the connecting shaft is one-third of the total length of the vertical frame, and the roller is movably connected to the outer side of the frame.
[0016] Protective plates can be fixed to the upper side of the forging base plate and the lower side of the forging hammer to protect the surfaces of the forging base plate and the forging hammer. Through the roller design and the setting of the protective plates, the frictional resistance during the movement of the vertical frame is reduced, the surfaces of the forging base plate and the forging hammer are protected, wear is reduced, and the stability of equipment operation and service life are improved.
[0017] The beneficial effects of this high-quality metal forging apparatus are as follows: Through an innovatively designed throwing mechanism and stabilizing structure, it solves many problems in the prior art, significantly improving the equipment's performance and service life. During the forging stage, the apparatus effectively restricts the movement of the forging base plate in both horizontal and vertical directions through the precise cooperation of the wedge-shaped clamping block with stabilizing grooves one and two, preventing displacement or vibration caused by impact. Simultaneously, the elastic design of the compression spring absorbs the kinetic energy generated by the forging hammer impact, converting it into potential energy and internal energy. This significantly reduces the impact force on the forging base plate and the receiving platform, significantly reducing wear and damage to components, extending the equipment's service life, and ensuring long-term operational stability and reliability.
[0018] During the material throwing stage, the same power system is used to precisely control the movement of the connecting shaft three via a servo electric cylinder-driven matching frame. This, in turn, adjusts the tilt angle of the forging base plate, allowing the material to slide down smoothly and controllably. This avoids impact problems caused by material splashing or rapid leaping, ensuring operational safety and material integrity. Furthermore, this design eliminates the need for additional power components, simplifying the equipment structure, reducing manufacturing costs and floor space, while simultaneously improving throwing efficiency. It adapts to the needs of materials with different qualities, densities, and sizes, demonstrating exceptional flexibility and practicality.
[0019] In summary, by integrating efficient ball-throwing and stable forging functions, this invention not only improves processing accuracy and safety but also significantly enhances the durability and economy of the equipment, providing an advanced solution for the metal forging industry. Attached Figure Description
[0020] To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:
[0021] Figure 1 This is a schematic diagram of the overall structure of the present invention;
[0022] Figure 2 This is a schematic diagram of the rear view structure of the present invention;
[0023] Figure 3 This is a schematic cross-sectional view of the side of the present invention;
[0024] Figure 4 This is a schematic diagram of the forged base plate of the present invention;
[0025] Figure 5 This is a schematic diagram of the structure of the present invention.
[0026] Reference numerals: 100, Frame assembly; 101, Base plate; 102, Frame; 103, Hydraulic press; 104, Hydraulic rod; 105, Forging hammer; 106, Receiving platform; 200, Throwing mechanism; 201, Forging base plate; 202, Recovery chamber; 203, Connecting plate; 204, Vertical frame; 205, Connecting shaft one; 206, Connecting shaft two; 207, Connecting shaft three; 208, Matching frame; 209, Control component; 210, Movable groove; 300, Stabilizing structure; 301, Connecting ring; 302, Limiting ring; 303, Extrusion rod; 304, Extrusion spring; 305, Clamping block; 306, Stabilizing groove one; 307, Stabilizing groove two; 308, Ash removal chamber. Detailed Implementation
[0027] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.
[0028] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.
[0029] Secondly, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that is mutually exclusive with other embodiments.
[0030] Secondly, the present invention is described in detail with reference to the schematic diagrams. When detailing the embodiments of the present invention, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not according to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of the present invention. In addition, actual fabrication should include three-dimensional spatial dimensions of length, width, and depth.
[0031] like Figures 1-5As shown, the present invention proposes a high-quality metal forging apparatus, including a frame assembly 100. The frame assembly 100 includes a base plate 101, a frame 102, a hydraulic press 103, a hydraulic rod 104, a forging hammer 105, and a receiving platform 106. The frame 102 is arranged on the upper side of the base plate 101. The hydraulic press 103 is arranged at the top of the frame 102. The hydraulic rod 104 is arranged at the bottom of the hydraulic press 103. The bottom end of the hydraulic rod 104 passes downward through the top of the frame 102 and connects to the forging hammer 105. The receiving platform 106 is arranged at the top of the base plate 101.
[0032] The throwing mechanism 200 includes a drive structure, a forging base plate 201, a connecting plate 203, and a vertical frame 204. The top of the receiving platform 106 has a groove, and the forging base plate 201 is movably connected in the groove. The lower side of the forging base plate 201 is movably connected to the inner bottom wall of the groove of the receiving platform 106. A vertical frame 204 is provided on each side of the groove. The inner cavity of the vertical frame 204 is provided with a connecting plate 203. The inner wall of the vertical frame 204 is rotatably connected to the connecting plate 203. One end of the vertical frame 204 is fixedly connected to the bottom of the forging base plate 201, and the other end of the connecting plate 203 is connected to the drive structure.
[0033] Stabilizing structure 300 is provided on the forging hammer 105.
[0034] The throwing mechanism 200 also includes a recovery chamber 202. The front of the receiving platform 106 is provided with a recovery chamber 202. The forging base plate 201 is L-shaped and is movably connected to the recovery chamber 202. The groove is connected to the recovery chamber 202.
[0035] By setting a recovery chamber on the receiving platform and movably connecting the L-shaped forged base plate to the recovery chamber, and with the groove connecting to the recovery chamber, material spillage is prevented, improving material throwing efficiency and operational cleanliness.
[0036] The stabilizing structure 300 includes a clamping block 305, a first stabilizing groove 306, a second stabilizing groove 307, a connecting ring 301, a limiting ring 302, a pressing rod 303, and a pressing spring 304. The clamping block 305 is wedge-shaped. The top of the forged base plate 201 has four first stabilizing grooves 306, and the upper side of the receiving platform 106 has four second stabilizing grooves 307. The first stabilizing groove 306 and the second stabilizing groove 307 correspond one-to-one. The shape of the top part of the clamping block 305 matches the shape of the first stabilizing groove 306, and the shape of the bottom part of the clamping block 305 matches the shape of the second stabilizing groove 307.
[0037] A connecting ring 301 is provided on each side of the forging hammer 105. A pressing rod 303 is movably inserted into the connecting ring 301. The bottom end of the pressing rod 303 is fixedly connected to the clamping block 305. A limit ring 302 is provided at the bottom of the pressing rod 303. A pressing spring 304 is sleeved on the top of the pressing rod 303. The top end of the pressing spring 304 is fixedly connected to the lower side of the connecting ring 301, and the bottom end of the pressing spring 304 is fixedly connected to the upper side of the limit ring 302. Through the matching design of the wedge-shaped clamping block and the first and second stabilizing grooves, combined with the buffering effect of the pressing spring, the movement of the forging base plate is effectively restricted, the impact kinetic energy is absorbed, the damage to the forging base plate and the receiving platform is reduced, and the equipment life is significantly extended.
[0038] The stabilizing structure 300 also includes a dust removal chamber 308. A dust removal chamber 308 is provided on each side of the receiving platform 106. A communication channel is provided between the dust removal chamber 308 and the second stabilizing tank 307. By providing dust removal chambers on both sides of the receiving platform and communicating with the second stabilizing tank, it is convenient to remove the residue generated during the forging process, keep the equipment clean, reduce wear and failure risks, and improve the stability of equipment operation. The residue generated during forging can slide down the channel by its own weight into the dust removal chamber 308, and dust removal can be completed without additional power.
[0039] The throwing mechanism 200 also includes a second connecting shaft 206. The connecting plate 203 near the forging base plate 201 is rotatably connected to the second connecting shaft 206. The second connecting shaft 206 is located in the vertical frame 204 and is fixedly installed inside the vertical frame 204. Through the rotatable connection and fixed installation of the second connecting shaft, the motion stability of the connecting plate and the vertical frame is enhanced, ensuring the accuracy and reliability of the tilting action of the forging base plate.
[0040] The driving structure includes a clamping structure and a linkage structure. The linkage structure includes a vertical frame 204, a first connecting shaft 205, and a third connecting shaft 207. The portion of the connecting plate 203 away from the forging base plate 201 has a movable groove 210. The first connecting shaft 205 is movably connected within the movable groove 210. The movable groove 210 is a blind groove. The middle section of the first connecting shaft 205 is rotatably connected to two vertical frames 204. The third connecting shaft 207 is located between the top ends of the two vertical frames 204 and is rotatably connected to the vertical frames 204. Through the design of the first connecting shaft, the third connecting shaft, and the movable groove in the linkage structure, the forging base plate can achieve a smooth tilting movement. Combined with the clamping structure, the throwing angle can be precisely controlled to adapt to different material requirements and improve throwing efficiency and flexibility.
[0041] The clamping structure includes a control component 209 and a matching frame 208. The matching frame 208 is C-shaped. A servo electric cylinder is installed inside the control component 209. The matching frame 208 is installed on the movable end of the servo electric cylinder. The matching frame 208 is movably sleeved with the connecting shaft 207. Through the clamping structure design of the C-shaped matching frame and the servo electric cylinder, precise clamping and synchronous movement of the connecting shaft 207 are achieved, simplifying the material throwing control process and improving the stability and automation of the action.
[0042] The clamping block 305 is wedge-shaped, and the angle between the outer side of the clamping block 305 and the vertical plane is 12 to 15 degrees.
[0043] By designing the angle between the outer side of the clamping block and the vertical plane to be 12 to 15 degrees, the limiting effect of the wedge structure is optimized, the stability of the forging base plate is enhanced, impact damage is reduced, and forging accuracy is improved.
[0044] The bottom end of the vertical frame 204, located below the connecting shaft 205, is rotatably connected to a roller. The length of the bottom end of the vertical frame 204, located below the connecting shaft 205, is one-third of the total length of the vertical frame 204. The roller is movably connected to the outer side of the frame 102.
[0045] The specific implementation method is as follows: Forging stage: The hydraulic rod 104 moves the forging hammer 105 up and down. During this stage, the forging hammer 105 performs a short stroke, allowing it to forge the forging base plate 201. Before the forging hammer 105 approaches the forging base plate 201, it inserts the clamping block 305 into the first stabilizing groove 306 and the second stabilizing groove 307 via the connecting ring 301, the compression spring 304, and the compression rod 303. The clamping block 305 causes the first stabilizing groove 306 and the second stabilizing groove 307 to... When the forging base plate 201 reaches its limit and cannot move, the elasticity of the compression spring 304 can reduce the impact generated by the clamping block 305. Due to the wedge-shaped structure of the clamping block 305, the upward or horizontal movement of the forging base plate 201 is restricted. When moving upward, the kinetic energy of the forging base plate 201 is absorbed by the compression spring 304 and converted into potential energy and internal energy, thereby greatly reducing the impact of the clamping block 305 on the forging base plate 201, reducing the damage to the forging base plate 201 and the receiving platform 106, and extending the service life.
[0046] Material throwing stage: The forging hammer 105 moves up to the height of the matching frame 208 corresponding to the connecting shaft 207. The servo electric cylinder in the control component 209 controls the matching frame 208 to hold the connecting shaft 207, so that the connecting shaft 207 moves synchronously with the forging hammer 105. The forging hammer 105 continues to move up, so that the vertical frame 204 moves vertically upward with the connecting shaft 205. The part of the vertical frame 204 located below the connecting shaft 205 is always restricted by the receiving platform 106 and remains vertical. The connecting shaft 205 swings with the connecting plate 203. The connecting plate 203 tilts the forging base plate 201, causing the material on the forging base plate 201 to slide off. The tilt angle of the forging base plate 201 can be controlled to accommodate materials of different qualities, densities, and sizes. The same power system is used. During this stage, the forging hammer 105 performs a long stroke. When the forging hammer 105 rises to the highest point, the tilt angle of the forging base plate 201 is the largest.
[0047] It should be understood that numerous specific implementation decisions can be made during the development of any practical implementation, such as in any engineering or design project. Such development efforts may be complex and time-consuming, but for those skilled in the art who benefit from this disclosure, the development effort will be a routine work of design, manufacturing, and production without requiring much experimentation.
[0048] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.
Claims
1. A high-quality metal forging apparatus, characterized in that: The frame assembly (100) includes a base plate (101), a frame (102), a hydraulic press (103), a hydraulic rod (104), a forging hammer (105), and a receiving platform (106). The frame (102) is provided on the upper side of the base plate (101). The hydraulic press (103) is provided at the top of the frame (102). The hydraulic rod (104) is provided at the bottom of the hydraulic press (103). The bottom end of the hydraulic rod (104) passes downward through the top of the frame (102) and is connected to the forging hammer (105). The receiving platform (106) is provided at the top of the base plate (101). The throwing mechanism (200) includes a drive structure, a forging base plate (201), a connecting plate (203) and a vertical frame (204). The top of the receiving platform (106) is provided with a groove, and the forging base plate (201) is movably connected in the groove. The lower side of the forging base plate (201) is movably connected to the inner bottom wall of the groove of the receiving platform (106). A connecting plate (203) is provided on each side of the groove. The inner wall of the groove is rotatably connected to the connecting plate (203). One end of the connecting plate (203) is fixedly connected to the bottom of the forging base plate (201), and the other end of the connecting plate (203) is connected to the drive structure. The throwing mechanism (200) also includes a recovery chamber (202). The front of the receiving platform (106) is provided with a recovery chamber (202). The forging base plate (201) is L-shaped. The forging base plate (201) is movably connected to the recovery chamber (202). The groove is connected to the recovery chamber (202). A stabilizing structure (300) is provided on the forging hammer (105); the stabilizing structure (300) also includes a dust removal chamber (308), and a dust removal chamber (308) is provided on each side of the receiving platform (106), and a communication channel is provided between the dust removal chamber (308) and the second stabilizing groove (307); the driving structure includes a clamping structure and a linkage structure, the linkage structure includes a vertical frame (204), a connecting shaft one (205) and a connecting shaft three (206). 207), the connecting plate (203) away from the forging base plate (201) has a movable groove (210), a connecting shaft (205) is movably connected in the movable groove (210), the movable groove (210) is a blind groove, the middle section of the connecting shaft (205) is rotatably connected to two vertical frames (204), a connecting shaft (207) is provided between the top ends of the two vertical frames (204), and the connecting shaft (207) is rotatably connected to the vertical frames (204).
2. The high-quality metal forging apparatus according to claim 1, characterized in that: The stabilizing structure (300) includes a clamping block (305), a first stabilizing groove (306), a second stabilizing groove (307), a connecting ring (301), a limiting ring (302), a pressing rod (303), and a pressing spring (304). The clamping block (305) is wedge-shaped. The top of the forged base plate (201) is provided with four first stabilizing grooves (306), and the upper side of the receiving platform (106) is provided with four second stabilizing grooves (307). The first stabilizing groove (306) and the second stabilizing groove (307) correspond one-to-one. The shape of the top part of the clamping block (305) matches the shape of the first stabilizing groove (306), and the shape of the bottom part of the clamping block (305) matches the shape of the second stabilizing groove (307). A connecting ring (301) is provided on each side of the forging hammer (105). A pressing rod (303) is movably inserted into the connecting ring (301). The bottom end of the pressing rod (303) is fixedly connected to the pressing block (305). A limit ring (302) is provided at the bottom of the pressing rod (303). A pressing spring (304) is sleeved on the top of the pressing rod (303). The top end of the pressing spring (304) is fixedly connected to the lower side of the connecting ring (301), and the bottom end of the pressing spring (304) is fixedly connected to the upper side of the limit ring (302).
3. The high-quality metal forging apparatus according to claim 1, characterized in that: The throwing mechanism (200) also includes a second connecting shaft (206). The second connecting shaft (206) is rotatably connected to the part of the connecting plate (203) near the forging base plate (201). The second connecting shaft (206) is located in the groove and is fixedly set in the groove.
4. The high-quality metal forging apparatus according to claim 1, characterized in that: The clamping structure includes a control component (209) and a matching frame (208). The matching frame (208) is C-shaped. A servo electric cylinder is installed inside the control component (209). The matching frame (208) is installed on the movable end of the servo electric cylinder. The matching frame (208) is movably connected to the connecting shaft three (207).
5. A high-quality metal forging apparatus according to claim 2, characterized in that: The clamping block (305) is wedge-shaped, and the angle between the outer side of the clamping block (305) and the vertical plane is 12 to 15 degrees.
6. The high-quality metal forging apparatus according to claim 1, characterized in that: The bottom end of the vertical frame (204) located below the connecting shaft (205) is rotatably connected to a roller. The length of the bottom end of the vertical frame (204) located below the connecting shaft (205) is one-third of the total length of the vertical frame (204). The roller is movably connected to the outside of the frame (102).