A continuous forging die for hinge production
By designing a continuous forging die, and utilizing a moving mechanism and a storage bin, the automated continuous forging of hinge components is achieved, solving the problem of low single-processing efficiency of existing dies and improving operational efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NOVA HARDWARE
- Filing Date
- 2025-04-10
- Publication Date
- 2026-06-26
AI Technical Summary
Existing forging dies can only process one hinge component at a time, which is cumbersome and has low forging efficiency.
A continuous forging die was designed, comprising a forging table, a forging head, a moving mechanism, a storage bin, and a feeding assembly. The moving mechanism enables automatic unloading, while the storage bin and feeding assembly enable automatic feeding and loading. The forging head is driven by a hydraulic cylinder for continuous forging.
It enables automated continuous forging of hinge components, improving forging efficiency and simplifying the operation process.
Smart Images

Figure CN224406349U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of hinge production and forging technology, and specifically relates to a continuous forging die for hinge production. Background Technology
[0002] Hinges need to be bent and forged during production, which requires the use of forging dies to bend and forge the hinges.
[0003] Existing forging dies generally include a forging table with a forging groove and a forging head for forging the hinge in the forging groove. During forging, the hinge component is placed in the forging groove, and a hydraulic device drives the forging head to press the hinge component, thereby bending and forging the hinge component in the forging groove. Existing forging dies can only process one hinge component at a time. After the hinge component is forged, it needs to be manually removed from the forging groove before a new hinge component can be placed in the forging groove for reforging. The operation is cumbersome and the forging efficiency is low. Utility Model Content
[0004] The purpose of this utility model is to provide a continuous forging die for hinge production, so as to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a continuous forging die for hinge production, comprising: a forging table with a processing chamber extending downwards from the top; a forging head for lifting and lowering forging is provided above the forging table; a forging seat for forging and supporting hinge components is provided in the processing chamber; a forging area for forging is formed between the forging seat and the forging head; and a moving mechanism connected to the forging seat is provided laterally in the forging table, the moving mechanism being used to drive the forging seat to open or close the bottom of the processing chamber.
[0006] Preferably, the forging table is also provided with a storage bin for feeding multiple hinge components laterally. One end of the storage bin extends into the forging area, and a feeding component is movably provided at the end of the storage bin away from the forging area. The feeding component is used to push multiple hinge components into the forging area in sequence.
[0007] Preferably, the feeding assembly includes a first electric push rod and a feeding block connected in sequence, with one end of the first electric push rod away from the feeding block installed at the end of the storage bin away from the forging area.
[0008] Preferably, a storage box for vertically storing multiple hinge components is provided above the forging table. The top of the forging table has a feed inlet connected to the storage bin. The bottom of the storage box is inserted into the feed inlet. The loading block is located on the side of the storage box away from the forging area.
[0009] Preferably, the moving mechanism includes a horizontal second electric actuator, and the forging table has a storage chamber that extends through the processing chamber. The second electric actuator is installed between the storage chamber and the forging seat, and the forging seat is movably installed in the storage chamber.
[0010] Preferably, a gantry frame connected to the forging table is provided above the processing chamber, and a hydraulic cylinder for lifting and adjusting is provided between the gantry frame and the forging head.
[0011] Compared with the prior art, this utility model has the following advantages:
[0012] (1) This utility model has a forging seat, a forging head and a moving mechanism added in the processing chamber. The moving mechanism can automatically open the bottom of the processing chamber after the hinge component is forged, so that the hinge component can be automatically unloaded.
[0013] (2) By adding a storage bin and a feeding assembly to the forging table, the present invention can push multiple hinge components into the forging area in sequence through the feeding assembly, thereby realizing the function of continuous forging of the equipment.
[0014] (3) By adding a storage box that cooperates with the storage bin, the present invention automatically adds multiple hinge components into the storage bin by gravity through the storage box, thereby realizing the function of automatic feeding of materials into the storage bin. Attached Figure Description
[0015] Figure 1 This is a front view of the present invention;
[0016] Figure 2 This is a first sectional view of the present invention;
[0017] Figure 3 This is a second sectional view of the present invention;
[0018] In the diagram: 1. Hydraulic cylinder; 2. Gantry frame; 3. Forging table; 4. Storage box; 5. Storage bin; 6. Feeding assembly; 7. Forging head; 8. Forging area; 9. Forging seat; 10. Storage bin; 11. Processing bin; 12. First electric actuator; 13. Feeding block; 14. Second electric actuator; 15. Feed inlet. Detailed Implementation
[0019] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0020] refer to Figure 1-3 As shown, the present invention provides a continuous forging die for hinge production, comprising: a forging table 3 with a processing chamber 11 extending downward from the top; a forging head 7 for lifting and forging is provided above the forging table 3; a forging seat 9 for forging and supporting hinge components is provided in the processing chamber 11; a forging area 8 for forging is formed between the forging seat 9 and the forging head 7; and a moving mechanism connected to the forging seat 9 is provided laterally in the forging table 3, the moving mechanism being used to drive the forging seat 9 to open or close the bottom of the processing chamber 11.
[0021] As described above, using the forging table 3, forging head 7, and moving mechanism provided by this utility model, the forging seat 9 is driven into the processing chamber 11 by the moving mechanism. At this time, the hinge component is placed in the forging area 8 at the top of the forging seat 9. The forging head 7 descends and forges the hinge component in the forging area 8. After forging is completed, the forging seat 9 is driven out of the processing chamber 11 by the moving mechanism, so that the forged hinge component is automatically unloaded through the bottom of the processing chamber 11, realizing the automatic unloading function of the equipment.
[0022] Furthermore, to facilitate the adjustment of the position of the forging stand 9, refer to... Figure 3 As shown, the moving mechanism includes a horizontal second electric actuator 14. A storage chamber 10, which extends through the processing chamber 11, is laterally opened in the forging table 3. The second electric actuator 14 is installed between the storage chamber 10 and the forging seat 9, which is movably installed in the storage chamber 10. The storage chamber 10 provides an installation position for the forging seat 9 and the second electric actuator 14 on one side of the processing chamber 11. After the hinge component is forged, the second electric actuator 14 is activated, driving the forging seat 9 from the processing chamber 11 into the storage chamber 10. At this time, the forged hinge component is disengaged from the forging seat 9, and the disengaged forging seat 9 is unloaded through the bottom of the processing chamber 11.
[0023] Furthermore, to facilitate the lifting and lowering adjustment of the forging head 7, refer to... Figure 1-3 As shown, a gantry frame 2 connected to the forging table 3 is provided above the processing chamber 11. A hydraulic cylinder 1 for lifting and adjusting is provided between the gantry frame 2 and the forging head 7. The hydraulic cylinder 1 is suspended above the forging head 7 by the gantry frame 2. When the hydraulic cylinder 1 is activated, it drives the forging head 7 to descend, thereby bending and forging the hinge component in the forging area 8.
[0024] In this utility model, combined with Figure 2-3 As shown, the forging table 3 of this embodiment is also provided with a storage bin 5 for feeding multiple hinge components laterally. One end of the storage bin 5 extends into the forging area 8. The end of the storage bin 5 away from the forging area 8 is provided with a feeding component 6, which is used to push multiple hinge components into the forging area 8 in sequence.
[0025] Combination Figure 3 As shown, the feeding assembly 6 includes a first electric push rod 12 and a feeding block 13 connected in sequence. The end of the first electric push rod 12 away from the feeding block 13 is installed at the end of the storage bin 5 away from the forging area 8.
[0026] As described above, when the feeding assembly 6 is horizontally installed in the forging head 7 via the storage bin 5 provided by this utility model, the first electric push rod 12 in the feeding assembly 6 is activated, driving the feeding block 13 to move in the storage bin 5, thereby pushing the hinge component in the storage bin 5 into the forging area 8, thus realizing the automatic feeding function of the equipment.
[0027] Furthermore, to facilitate the feeding of materials into storage bin 10, refer to Figure 1-3 As shown, a storage box 4 for vertically storing multiple hinge components is also provided above the forging table 3. The top of the forging table 3 has a feed inlet 15 connected to the storage bin 5. The bottom end of the storage box 4 is inserted into the feed inlet 15, and the loading block 13 is located on the side of the storage box 4 away from the forging area 8. Multiple hinge components are sequentially stacked and installed in the storage box 4. The storage box 4 has an open top and bottom box-like structure. The storage box 4 is inserted into the feed inlet 15. At this time, the multiple hinge components in the storage box 4 are stacked in the storage bin 5. After the loading block 13 feeds the hinge components, the stacked hinge components sequentially enter the storage bin 5, realizing the automatic feeding function of the equipment.
[0028] 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 hinge-based continuous forging die, characterized in that, include: A forging table (3) with a processing chamber (11) extending downwards from the top is provided. A forging head (7) for lifting and forging is provided above the forging table (3). A forging seat (9) for forging support hinge components is provided in the processing chamber (11). A forging area (8) for forging is formed between the forging seat (9) and the forging head (7). A moving mechanism connected to the forging seat (9) is provided laterally in the forging table (3). The moving mechanism is used to drive the forging seat (9) to open or close the bottom of the processing chamber (11).
2. The hinge production continuous forging die according to claim 1, characterized in that: The forging table (3) is also provided with a storage bin (5) for feeding multiple hinge components laterally. One end of the storage bin (5) extends into the forging area (8). The end of the storage bin (5) away from the forging area (8) is provided with a feeding component (6). The feeding component (6) is used to push multiple hinge components into the forging area (8) in sequence.
3. The hinge production continuous forging die according to claim 2, characterized in that: The feeding assembly (6) includes a first electric push rod (12) and a feeding block (13) connected in sequence. The end of the first electric push rod (12) away from the feeding block (13) is installed at the end of the storage bin (5) away from the forging area (8).
4. A hinge production continuous forging die according to claim 3, characterized in that: Above the forging table (3) is a storage box (4) for storing multiple hinge components vertically. The top of the forging table (3) is provided with a feed inlet (15) connected to the storage bin (5). The bottom end of the storage box (4) is inserted into the feed inlet (15). The loading block (13) is located on the side of the storage box (4) away from the forging area (8).
5. A hinge production continuous forging die according to claim 1, characterized in that: The moving mechanism includes a horizontal second electric actuator (14), and a storage chamber (10) that passes through the processing chamber (11) is provided in the forging table (3). The second electric actuator (14) is installed between the storage chamber (10) and the forging seat (9), and the forging seat (9) is movably installed in the storage chamber (10).
6. A hinge production continuous forging die according to claim 1, characterized in that: Above the processing chamber (11) is a gantry frame (2) connected to the forging table (3), and a hydraulic cylinder (1) for lifting and adjusting is provided between the gantry frame (2) and the forging head (7).